Telecommunications apparatus and methods

ABSTRACT

A method of operating first and second terminal devices for transmitting data in a device-to-device communication mode in a wireless telecommunications system supporting communications on a first carrier operating over a first frequency band and a second carrier operating over a second frequency band. The first terminal device transmits control signalling on the first carrier and this is received by the second terminal device. The control signalling comprises an indication of an allocation of radio resource blocks on the second carrier to be used for transmitting user-plane data from the first terminal device to the second terminal device. The first terminal device then proceeds to transmit the user-plane data to the second terminal device on the second carrier using the radio resource blocks on the second carrier identified by the control signalling. The control signalling may also provide an indication of an allocation of radio resource blocks on the first carrier to be used for transmitting user-plane data to the second terminal device.

BACKGROUND Field

The present disclosure relates to telecommunications apparatus andmethods, and in particular to telecommunications apparatus and methodsfor use in wireless telecommunications systems in which terminal devicesare configured to perform device-to-device communications.

Description of Related Art

The “background” description provided herein is for the purpose ofgenerally presenting the context of the disclosure. Work of thepresently named inventors, to the extent it is described in thisbackground section, as well as aspects of the description which may nototherwise qualify as prior art at the time of filing, are neitherexpressly or impliedly admitted as prior art against the presentinvention.

Mobile telecommunication systems, such as those based on the 3GPPdefined UMTS and Long Term Evolution (LTE) architecture, are able tosupport more sophisticated services than simple voice and messagingservices offered by previous generations of mobile telecommunicationsystems. For example, with the improved radio interface and enhanceddata rates provided by LTE systems, a user is able to enjoy high datarate applications such as video streaming and video conferencing onmobile communications devices that would previously only have beenavailable via a fixed line data connection.

The demand to deploy fourth generation networks is therefore strong andthe coverage area of these networks, i.e. geographic locations whereaccess to the networks is possible, is expected to increase rapidly.However, although the coverage and capacity of fourth generationnetworks is expected to significantly exceed those of previousgenerations of communications networks, there are still limitations onnetwork capacity and the geographical areas that can be served by suchnetworks. These limitations may, for example, be particularly relevantin situations in which networks are experiencing high load and high-datarate communications between communications devices, or whencommunications between communications devices are required but thecommunications devices may not be within reliable coverage of a basestation supporting communications in the network. In order to helpaddress these limitations there have been proposed approaches in whichterminal devices (communications devices) within a wirelesstelecommunications system may be configured to communicate data directlywith one another without some or all communications passing through aninfrastructure equipment element, such as a base station. Suchcommunications are commonly referred to as a device-to-device (D2D)communications.

Thus, D2D communications allow communications devices that are insufficiently close proximity to directly communicate with each other,both when within the coverage area of a network and when outside anetwork's coverage area (e.g. due to geographic restrictions on anetwork's extent or because the network has failed or is in effectunavailable to a terminal device because the network is overloaded). D2Dcommunications can allow user data to be more efficiently communicatedbetween communications devices by obviating the need for user data to berelayed by a network entity such as a base station, and also allowscommunications devices to communicate with one another when one or bothdevices may not be within the reliable coverage area of a network. Theability for communications devices to operate both inside and outside ofcoverage areas makes wireless telecommunications systems thatincorporate D2D capabilities well suited to applications such as publicsafety communications, for example. Public safety communications maybenefit from a high degree of robustness whereby devices can continue tocommunicate with one another in congested networks and when outside acoverage area.

Fourth generation networks have therefore been proposed as a costeffective solution to public safety communications compared to dedicatedsystems such as TETRA (terrestrial trunked radio) which are currentlyused throughout the world.

The inventors have recognised one issue for consideration for D2Dcommunications is how to help reduce the processing load associated withterminal devices monitoring for D2D communications they are to receive,especially in situations where there may be relatively large amounts ofdata being communicated to the terminal device in a D2D mode. Thus thereis a need for apparatus and methods that can help with addressing theseissues.

SUMMARY

According to an aspect of the disclosure there is provided a method ofoperating a first terminal device for transmitting data to a secondterminal device in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band; the method comprising: transmitting on thefirst carrier control signalling comprising an indication of radioresources on the second carrier to be used for transmitting user-planedata from the first terminal device to the second terminal device; andtransmitting user-plane data to the second terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

According to an aspect of the disclosure there is provided a firstterminal device for transmitting data to a second terminal device in adevice-to-device communication mode in a wireless telecommunicationssystem supporting communications on a first carrier operating over afirst frequency band and a second carrier operating over a secondfrequency band, wherein the first terminal device comprises a controllerunit and a transceiver unit configured to operate together to transmiton the first carrier control signalling comprising an indication ofradio resources on the second carrier to be used for transmittinguser-plane data from the first terminal device to the second terminaldevice; and transmit user-plane data to the second terminal device onthe second carrier using the radio resources on the second carrierindicated by the control signalling.

According to an aspect of the disclosure there is provided circuitry fora first terminal device for transmitting data to a second terminaldevice in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band, wherein the circuitry comprises acontroller element and a transceiver element configured to operatetogether to cause the first terminal device to: transmit on the firstcarrier control signalling comprising an indication of radio resourceson the second carrier to be used for transmitting user-plane data fromthe first terminal device to the second terminal device; and transmituser-plane data to the second terminal device on the second carrierusing the radio resources on the second carrier indicated by the controlsignalling.

According to an aspect of the disclosure there is provided a method ofoperating a second terminal device for receiving data from a firstterminal device in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band; the method comprising: receiving on thefirst carrier control signalling comprising an indication of radioresources on the second carrier to be used by the first terminal devicefor transmitting user-plane data to the second terminal device; andreceiving user-plane data from the first terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

According to an aspect of the disclosure there is provided a secondterminal device for receiving data from a first terminal device in adevice-to-device communication mode in a wireless telecommunicationssystem supporting communications on a first carrier operating over afirst frequency band and a second carrier operating over a secondfrequency band, wherein the second terminal device comprises acontroller unit and a transceiver unit configured to operate togetherto: receive on the first carrier control signalling comprising anindication of radio resources on the second carrier to be used by thefirst terminal device for transmitting user-plane data to the secondterminal device; and receive user-plane data from the first terminaldevice on the second carrier using the radio resources on the secondcarrier indicated by the control signalling.

According to an aspect of the disclosure there is provided circuitry fora second terminal device for receiving data from a first terminal devicein a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band, wherein the circuitry comprises acontroller element and a transceiver element configured to operatetogether to cause the second terminal device to: receive on the firstcarrier control signalling comprising an indication of radio resourceson the second carrier to be used by the first terminal device fortransmitting user-plane data to the second terminal device; and receiveuser-plane data from the first terminal device on the second carrierusing the radio resources on the second carrier indicated by the controlsignalling.

Further respective aspects and features are defined by the appendedclaims.

The foregoing paragraphs have been provided by way of generalintroduction, and are not intended to limit the scope of the followingclaims. The described embodiments, together with further advantages,will be best understood by reference to the following detaileddescription taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of the disclosure and many of the attendantadvantages thereof will be readily obtained as the same becomes betterunderstood by reference to the following detailed description whenconsidered in connection with the accompanying drawings wherein likereference numerals designate identical or corresponding parts throughoutthe several views, and wherein:

FIG. 1 provides a schematic diagram illustrating an example of a mobiletelecommunication system;

FIG. 2A provides a schematic diagram illustrating a LTE downlink radioframe;

FIG. 2B provides a schematic diagram illustrating an example of a LTEdownlink radio subframe;

FIG. 3 provides a schematic diagram illustrating an example of a LTEuplink radio subframe;

FIG. 4 provides a schematic diagram illustrating an example of a D2Dframe structure;

FIG. 5 schematically represents a wireless telecommunications systemaccording to an embodiment of the disclosure;

FIGS. 6 to 10 schematically represent radio resources used forcommunicating user-plane data from a first terminal device to a secondterminal device and associated resource allocation signalling on firstand second carriers in accordance with certain embodiments of thedisclosure;

FIG. 11 is a ladder diagrams schematically representing methods ofoperation in accordance with certain embodiments of the disclosure;

FIG. 12 schematically represents radio resources used for communicatinguser-plane data from a first terminal device to a second terminal deviceand associated resource allocation signalling on first and secondcarriers in accordance with certain embodiments of the disclosure; and

FIG. 13 is a ladder diagrams schematically representing methods ofoperation in accordance with certain embodiments of the disclosure;

DETAILED DESCRIPTION OF THE EMBODIMENTS

FIG. 1 provides a schematic diagram illustrating some basicfunctionality of a mobile telecommunications network/system 100operating in accordance with LTE principles and which may be adapted toimplement embodiments of the disclosure as described further below.Various elements of FIG. 1 and their respective modes of operation arewell-known and defined in the relevant standards administered by the3GPP (RTM) body and also described in many books on the subject, forexample, Holma H. and Toskala A [1]. It will be appreciated thatoperational aspects of the telecommunications network which are notspecifically described below may be implemented in accordance with anyknown techniques, for example according to the relevant standards orvariations thereof.

The network 100 includes a plurality of base stations 101 connected to acore network 102. Each base station provides a coverage area 103 (i.e. acell) within which data can be communicated to and from terminal devices104. Data is transmitted from base stations 101 to terminal devices 104within their respective coverage areas 103 via a radio downlink. Data istransmitted from terminal devices 104 to the base stations 101 via aradio uplink. The core network 102 routes data to and from the terminaldevices 104 via the respective base stations 101 and provides functionssuch as authentication, mobility management, charging and so on.Terminal devices may also be referred to as mobile stations, userequipment (UE), user terminal, mobile radio, and so forth. Base stationsmay also be referred to as transceiver stations/nodeBs/e-nodeBs, and soforth.

Mobile telecommunications systems such as those arranged in accordancewith the 3GPP defined Long Term Evolution (LTE) architecture use anorthogonal frequency division modulation (OFDM) based interface for theradio downlink (so-called OFDMA) and a single carrier frequency divisionmultiple access scheme (SC-FDMA) on the radio uplink.

FIG. 2A shows a schematic diagram illustrating an OFDM based LTEdownlink radio frame 201. The LTE downlink radio frame is transmittedfrom a LTE base station (known as an enhanced Node B) and lasts 10 ms.The downlink radio frame comprises ten subframes, each subframe lasting1 ms. A primary synchronisation signal (PSS) and a secondarysynchronisation signal (SSS) are transmitted in the first and sixthsubframes of the LTE frame. A physical broadcast channel (PBCH) istransmitted in the first subframe of the LTE frame.

FIG. 2B is a schematic diagram of a grid which illustrates the structureof an example conventional downlink LTE subframe. The subframe comprisesa predetermined number of symbols which are transmitted over a 1 msperiod. Each symbol comprises a predetermined number of orthogonalsubcarriers distributed across the bandwidth of the downlink radiocarrier.

The example subframe shown in FIG. 2B comprises 14 symbols and 1200subcarriers spread across a 20 MHz bandwidth and in this example is thefirst subframe in a frame (hence it contains PBCH). The smallestallocation of physical resource for transmission in LTE is a resourceblock comprising twelve subcarriers transmitted over one subframe. Forclarity, in FIG. 2B, each individual resource element is not shown,instead each individual box in the subframe grid corresponds to twelvesubcarriers transmitted on one symbol.

FIG. 2B shows in hatching resource allocations for four LTE terminals340, 341, 342, 343. For example, the resource allocation 342 for a firstLTE terminal (UE 1) extends over five blocks of twelve subcarriers (i.e.60 subcarriers), the resource allocation 343 for a second LTE terminal(UE2) extends over six blocks of twelve subcarriers (i.e. 72subcarriers), and so on.

Control channel data can be transmitted in a control region 300(indicated by dotted-shading in FIG. 2B) of the subframe comprising thefirst “n” symbols of the subframe where “n” can vary between one andthree symbols for channel bandwidths of 3 MHz or greater and where “n”can vary between two and four symbols for a channel bandwidth of 1.4MHz. For the sake of providing a concrete example, the followingdescription relates to host carriers with a channel bandwidth of 3 MHzor greater so the maximum value of “n” will be 3 (as in the example ofFIG. 2B). The data transmitted in the control region 300 includes datatransmitted on the physical downlink control channel (PDCCH), thephysical control format indicator channel (PCFICH) and the physical HARQindicator channel (PHICH). These channels transmit physical layercontrol information. Control channel data can also or alternatively betransmitted in a second region of the subframe comprising a number ofsubcarriers for a time substantially equivalent to the duration of thesubframe, or substantially equivalent to the duration of the subframeremaining after the “n” symbols. The data transmitted in this secondregion is transmitted on the enhanced physical downlink control channel(EPDCCH). This channel transmits physical layer control informationwhich may be in addition to that transmitted on other physical layercontrol channels.

PDCCH and EPDCCH contain control data indicating which subcarriers ofthe subframe have been allocated by a base station to specific terminals(or all terminals or subset of terminals). This may be referred to asphysical-layer control signalling/data. Thus, the PDCCH and/or EPDCCHdata transmitted in the control region 300 of the subframe shown in FIG.2B would indicate that UE1 has been allocated the block of resourcesidentified by reference numeral 342, that UE2 has been allocated theblock of resources identified by reference numeral 343, and so on.

PCFICH contains control data indicating the size of the control region(i.e. between one and three symbols for channel bandwidths of 3 MHz orgreater and between two and four symbols for channel bandwidths of 1.4MHz).

PHICH contains HARQ (Hybrid Automatic Request) data indicating whetheror not previously transmitted uplink data has been successfully receivedby the network.

Symbols in a central band 310 of the time-frequency resource grid areused for the transmission of information including the primarysynchronisation signal (PSS), the secondary synchronisation signal (SSS)and the physical broadcast channel (PBCH). This central band 310 istypically 72 subcarriers wide (corresponding to a transmission bandwidthof 1.08 MHz). The PSS and SSS are synchronisation signals that oncedetected allow a LTE terminal device to achieve frame synchronisationand determine the physical layer cell identity of the enhanced Node Btransmitting the downlink signal. The PBCH carries information about thecell, comprising a master information block (MIB) that includesparameters that LTE terminals use to properly access the cell. Datatransmitted to terminals on the physical downlink shared channel(PDSCH), which may also be referred to as a downlink data channel, canbe transmitted in other resource elements of the subframe. In generalPDSCH conveys a combination of user-plane data and non-physical layercontrol-plane data (such as Radio Resource Control (RRC) and Non AccessStratum (NAS) signalling). The user-plane data and non-physical layercontrol-plane data conveyed on PDSCH may be referred to as higher layerdata (i.e. data associated with a layer higher than the physical layer).

FIG. 2B also shows a region of PDSCH containing system information andextending over a bandwidth of R344. A conventional LTE subframe willalso include reference signals which are discussed further below but notshown in FIG. 2B in the interests of clarity.

The number of subcarriers in a LTE channel can vary depending on theconfiguration of the transmission network. Typically this variation isfrom 72 sub carriers contained within a 1.4 MHz channel bandwidth to1200 subcarriers contained within a 20 MHz channel bandwidth (asschematically shown in FIG. 2B). As is known in the art, datatransmitted on the PDCCH, PCFICH and PHICH is typically distributed onthe subcarriers across the entire bandwidth of the subframe to providefor frequency diversity.

FIG. 3 is a schematic diagram which illustrates some aspects of thestructure of an example conventional uplink LTE subframe. In LTEnetworks the uplink wireless access interface is based upon a singlecarrier frequency division multiple access (SC-FDMA) interface anddownlink and uplink wireless access interfaces may be provided byfrequency division duplexing (FDD) or time division duplexing (TDD). InTDD implementations subframes switch between uplink and downlinksubframes in accordance with predefined patterns and in FDDimplementations the uplink and downlink channels are separated byfrequency. Regardless of the form of duplexing used, a common uplinkframe structure is utilised in LTE. The simplified representation ofFIG. 3 illustrates such an uplink frame at different levels ofresolution with a frame 400 of the uplink frame structure represented atthe bottom of the figure, a subframe 401 represented in the middle ofthe figure, and a slot 402 represented at the top of the figure. Thusthe frame 400 is divided in to 10 subframes 401 of 1 ms duration whereeach subframe 401 comprises two slots 402 of 0.5 ms duration. Each slotis then formed from seven OFDM symbols 403 (numbered 0 to 6 in FIG. 3)where a cyclic prefix 404 is inserted between each symbol. In FIG. 3 anormal cyclic prefix is used and therefore there are seven OFDM symbolswithin a subframe, however, if an extended cyclic prefix were to beused, each slot would contain only six OFDM symbols. The resources ofthe uplink subframes are also divided into resource blocks and resourceelements in a broadly similar manner to downlink subframes.

As is well known, each uplink subframe may include a plurality ofdifferent channels, for example a physical uplink shared channel (PUSCH)405, a physical uplink control channel (PUCCH) 406, which may takevarious formats, and a physical random access channel (PRACH). Thephysical Uplink Control Channel (PUCCH) may carry control informationsuch as ACK/NACK to the base station for downlink transmissions,scheduling request indicators (SRI) for terminal devices wishing to bescheduled uplink resources, and feedback of downlink channel stateinformation (CSI) for example. The PUSCH may carry terminal deviceuplink data or some uplink control data. Resources of the PUSCH aregranted via PDCCH, such a grant being typically triggered bycommunicating to the network the amount of data ready to be transmittedin a buffer at the terminal device. The PRACH may be scheduled in any ofthe resources of an uplink frame in accordance with one of a pluralityof PRACH patterns that may be signalled to terminal device in downlinksignalling such as system information blocks. As well as physical uplinkchannels, uplink subframes may also include reference signals. Forexample, demodulation reference signals (DMRS) 407 and soundingreference signals (SRS) 408 may be present in an uplink subframe wherethe DMRS occupy the fourth symbol of a slot in which PUSCH istransmitted and are used for decoding of PUCCH and PUSCH data, and whereSRS are used for uplink channel estimation at the base station. Furtherinformation on the structure and functioning of the physical channels ofLTE systems can be found in reference [1].

In an analogous manner to the resources of the PDSCH for downlinkcommunications, resources of the PUSCH for uplink communications arescheduled or granted by the serving base station. Thus for data is to betransmitted by a terminal device, resources of the PUSCH are granted tothe terminal device by the base station. At a terminal device, PUSCHresource allocation is achieved by the transmission of a schedulingrequest or a buffer status report to its serving base station. Thescheduling request may be made, when there is insufficient uplinkresource for the terminal device to send a buffer status report, via thetransmission of Uplink Control Information (UCI) on the PUCCH when thereis no existing PUSCH allocation for the terminal device, or bytransmission directly on the PUSCH when there is an existing PUSCHallocation for the terminal device. In response to a scheduling request,the base station is configured to allocate a portion of the PUSCHresource to the requesting terminal device sufficient for transferring abuffer status report and then inform the terminal device of the bufferstatus report resource allocation via a DCI in the PDCCH.

Although similar in overall structure to downlink subframes, uplinksubframes have a different control structure to downlink subframes, inparticular an upper region 409 and a lower region 410 ofsubcarriers/frequencies/resource blocks of an uplink subframe arereserved for control signalling (as opposed to the initial symbols for adownlink subframe). Furthermore, although the resource allocationprocedure for the downlink and uplink are similar, the actual structureof the resources that may be allocated may vary due to the differentcharacteristics of the OFDM and SC-FDMA interfaces used in the downlinkand uplink respectively. For example, for OFDM each subcarrier may beindividually modulated and therefore it is not particularly significantwhether frequency/subcarrier allocations are contiguous. However, forSC-FDMA the subcarriers are modulated in combination and therefore itcan be more efficient to allocate contiguous frequency allocations foreach terminal device.

As a result of the above described wireless interface structure andoperation, one or more terminal devices may communicate data with oneanother via a coordinating base station, thus forming a conventionalcellular telecommunications system. However, as noted above, there arealso approaches for additionally allowing terminal devices tocommunicate directly with one another (i.e. without communicationspassing through a coordinating base station) using so-calleddevice-to-device (D2D) modes of operation. As explained further below,it is expected that in at least some modes of D2D operation a subset ofa network's radio resources will be reserved for D2D communications.

FIG. 4 schematically represents a D2D frame structure 450 in an LTERelease 12 context. The basic frame structure 450 comprises a repeatingpattern of D2D subframes 452 having a duration of “sc-Period” 454 withframe boundaries offset from the wireless telecommunications systemframe number (SFN) by an amount “offset” 456. In a manner which isbroadly similar to a LTE downlink subframe, each D2D subframe comprisesa control region 458 and a higher-layer data region 460. Controlsignalling in the control region is used to provide indications of dataresource allocations in the high-layer data region in respect of D2Dtransmissions. The respective control regions 458 are configured using asubframe bitmap 462 indicating regions of side-link control (SC)resources 464 while the other resources 466 are used for the wirelessaccess network (WAN). These may be distributed in frequency acrossregions of side-link control physical resource blocks 474, whereby otherregions contain physical uplink control channel (PUCCH) resources 470and WAN physical resource blocks 472, as schematically represented inFIG. 4.

FIG. 5 schematically shows a telecommunications system 500 according toan embodiment of the disclosure. The telecommunications system 500 inthis example is based broadly on a LTE-type architecture withmodifications to support device-to-device communications (i.e. directsignalling exchange between terminal devices to communicate data betweenthem) generally in accordance with previously proposed schemes for D2Dcommunications. As such many aspects of the operation of thetelecommunications system 500 are already known and understood and notdescribed here in detail in the interest of brevity. Operational aspectsof the telecommunications system 500 which are not specificallydescribed herein may be implemented in accordance with any knowntechniques, for example according to the established LTE-standards andknown variations and modifications thereof (e.g. to provide/introducesupport for D2D communications).

The telecommunications system 500 comprises a core network part (evolvedpacket core) 502 coupled to a radio network part. The radio network partcomprises a base station (evolved-nodeB) 504, a first terminal device506 and a second terminal device 508. It will of course be appreciatedthat in practice the radio network part may comprise a plurality of basestations serving a larger number of terminal devices across variouscommunication cells. However, only a single base station and twoterminal devices are shown in FIG. 5 in the interests of simplicity.

As with a conventional mobile radio network, the terminal devices 506,508 are arranged to communicate data to and from the base station(transceiver station) 504. The base station is in turn communicativelyconnected to a serving gateway, S-GW, (not shown) in the core networkpart which is arranged to perform routing and management of mobilecommunications services to the terminal devices in thetelecommunications system 500 via the base station 504. In order tomaintain mobility management and connectivity, the core network part 502also includes a mobility management entity (not shown) which manages theenhanced packet service, EPS, connections with the terminal devices 506,508 operating in the communications system based on subscriberinformation stored in a home subscriber server, HSS. Other networkcomponents in the core network (also not shown for simplicity) include apolicy charging and resource function, PCRF, and a packet data networkgateway, PDN-GW, which provides a connection from the core network part502 to an external packet data network, for example the Internet. Asnoted above, the operation of the various elements of the communicationssystem 500 shown in FIG. 5 may be broadly conventional apart from wheremodified to provide functionality in accordance with embodiments of thedisclosure as discussed herein.

The first and second terminal devices 506, 508 are D2D enabled devicesconfigured to operate in accordance with embodiments of the presentdisclosure as described herein. The terminal devices 506, 508 eachcomprise a transceiver unit 506 a, 508 a for transmission and receptionof wireless signals and a controller unit 506 b, 508 b configured tocontrol the respective terminal devices 506, 508. The respectivecontroller units 506 b, 508 b may each comprise a processor unit whichis suitably configured/programmed to provide the desired functionalityusing conventional programming/configuration techniques for equipment inwireless telecommunications systems. The respective transceiver units506 a, 508 a and controller units 506 b, 508 b are schematically shownin FIG. 5 as separate elements. However, it will be appreciated for eachof the terminal devices the functionality of the terminal devicesreceiver and controller units can be provided in various different ways,for example using a single suitably programmed general purpose computer,or suitably configured application-specific integratedcircuit(s)/circuitry. It will be appreciated the first and secondterminal devices 506, 508 will in general comprise various otherelements associated with their operating functionality in accordancewith established wireless telecommunications techniques (e.g. a powersource, possibly a user interface, and so forth).

The base station 504 is configured to support communications with theterminal devices and may also play a role in configuring aspects of D2Dcommunications between the terminal devices, for example establishingwhich radio resources may be used for D2D communications betweenterminal devices operating within the coverage area of the base station504. The base station 504 comprises a transceiver unit 504 a fortransmission and reception of wireless signals and a controller unit 504b configured to control the base station 504. The controller unit 504 bmay comprise a processor unit which is suitably configured/programmed toprovide the desired functionality using conventionalprogramming/configuration techniques for equipment in wirelesstelecommunications systems. The transceiver unit 504 a and thecontroller unit 504 b are schematically shown in FIG. 5 as separateelements for ease of representation. However, it will be appreciatedthat the functionality of these units can be provided in variousdifferent ways, for example using a single suitably programmed generalpurpose computer, or suitably configured application-specific integratedcircuit(s)/circuitry or using a plurality of discretecircuitry/processing elements for providing different elements of thedesired functionality. It will be appreciated the base station 504 willin general comprise various other elements associated with its operatingfunctionality. For example, the base station 504 will in generalcomprise a scheduling entity responsible for scheduling communications.The functionality of the scheduling entity may, for example, be subsumedby the controller unit 504 b.

Thus, the base station 504 is configured to communicate data with thefirst terminal device 506 over a first radio communication link 510 andcommunicate data with the second terminal device 508 over a second radiocommunication link 512. Both radio links may be supported within asingle radio frame structure associated with the base station 504. It isassumed here the base station 504 is configured to communicate with theterminal devices 506, 508 over the respective radio communication links510, 512 generally in accordance with the established principles ofLTE-based communications.

However, in addition to the terminal devices 506, 508 being arranged tocommunicate data to and from the base station (transceiver station) 504over the respective first and second radio communication links 510, 512,the terminal devices 506, 508 are further arranged to communicate withone another (and other terminal devices within the wirelesstelecommunications system) in a device-to-device (D2D) manner over a D2Dradio communication link 514, as schematically indicated in the figure.The underlying principles of the D2D communications supported in thewireless telecommunications system of FIG. 5 may follow any previouslyproposed techniques, but with modifications to support approaches inaccordance with embodiments of the disclosure as described herein.

There are a number of possible approaches to the implementation of D2Dcommunications within an LTE-based wireless telecommunications systemthat have been proposed for different scenarios.

Some approaches may rely on a coordinating entity, such as a basestation or other network entity, to allocate specific transmissionresources for use by respective terminal devices to transmit data. Forexample, resources within the wireless access interface provided forcommunications between terminal devices and a base station may be usedfor D2D communications and a base station may allocate resources forspecific D2D communications. That is to say, the base station may beresponsible for scheduling which terminal devices transmit D2Dcommunications on which resources in a broadly similar manner to the wayin which the base station is responsible for scheduling conventionaluplink communications. Thus terminal devices may receive controlsignalling from the base station to indicate which resources they shoulduse for transmitting user data to another terminal device in a D2Dmanner. This type of approach may generally be referred to as a Mode 1approach.

Other approaches may not rely on any coordinating entity for managingaccess to radio resources by terminal devices undertaking D2Dcommunications. For example it has been proposed in document R2-133840[2] to use a Carrier Sense Multiple Access, CSMA, approach to provide adegree of co-ordination for D2D transmissions by terminal devicesthrough contention based scheduling by each terminal device. In effecteach terminal device first listens to identify which resources arecurrently being used, and then schedules its own transmissions on unusedresources. This type of approach may generally be referred to as a Mode2 approach.

Thus, in some respects, a Mode 1 approach may be seen as an approach inwhich access to resources for D2D communications is scheduled by acoordinating entity whereas a Mode 2 approach may be seen as an approachin which access to resources for D2D communications are not scheduled bya coordinating entity and are contention based.

Some proposed arrangements include those in which a terminal device actsas a controlling entity for a group of terminal devices to co-ordinatetransmissions of the other members of the group. Examples of suchproposals are provided in the following disclosures:

[3] R2-133990, Network control for Public Safety D2D Communications;Orange, Huawei, HiSilicon, Telecom Italia

[4] R2-134246, The Synchronizing Central Node for Out of Coverage D2DCommunication; General Dynamics Broadband UK

[5] R2-134426, Medium Access for D2D communication; LG Electronics Inc

In some respects these approaches may be seen as variations of a Mode 1approach in which a “master” terminal device plays a role correspondingto that of a base station in allocating (scheduling) D2D resources amongterminal devices wishing make D2D communications.

In other arrangements a transmitting terminal device operating in agroup of D2D capable devices and which has data to transmit to one ormore of the other terminal devices in the group may first send ascheduling assignment (side-link control) message providing anindication of radio resources which the transmitting terminal deviceintends to use for communicating the D2D data. The transmitting terminaldevice may then transmit the D2D data on the indicated radio resourceswithout a central scheduling terminal device or controlling entitycontrolling the transmissions. The following disclosures provideexamples of this de-centralised arrangement:

[6] R2-134238, D2D Scheduling Procedure; Ericsson;

[7] R2-134248, Possible mechanisms for resource selection inconnectionless D2D voice communication; General Dynamics Broadband UK;

[8] R2-134431, Simulation results for D2D voice services usingconnectionless approach, General Dynamics Broadband UK

In particular, the last two disclosures listed above, R2-134248 [7],R2-134431 [8], disclose the use of a scheduling channel, used byterminal devices to indicate their intention to schedule data along withthe resources that will be used. The other disclosure, R2-134238 [6],does not use a scheduling channel as such, but deploys at least somepredefined resources to send the scheduling assignments (side-linkcontrol). These approaches may be seen as Mode 2 type approaches.

Other example arrangements disclosed in [9] and [10] require a basestation to provide feedback to the communications devices to controltheir transmissions. Document [11] discloses an arrangement in which adedicated resource exchanging channel is provided between cellular userequipment and device-to-device user equipment for interference controland resource coordination.

It is to be expected that device-to-device communications whenimplemented in the context of an existing LTE-based wirelesstelecommunications network will use transmission resources associatedwithin the existing LTE radio interface. In particular, it is expectedthat device-to-device communications will use radio resources fromwithin the existing LTE uplink frame structure. There are variousreasons for this. For example, traffic profiles in wirelesstelecommunications systems are typically such that an uplink channel ismore likely to have more spare capacity then a downlink channel.Furthermore, the downlink channel is associated with more powerfultransmissions from a base station and these are more likely to swamp andinterfere with device-to-device communications.

One factor that is expected to be significant in determining the mannerin which terminal devices undertake D2D communications is the extent towhich the terminal devices are within network coverage. For example,terminal devices which are outside network coverage may be expected tooperate according to Mode 2 in the absence of any coordinatinginformation from a base station (although such terminal devices couldoperate in accordance with Mode 1 with a selected terminal device takingon the role of centralised scheduling/coordination). Terminal deviceswithin network coverage might be expected to operate according to Mode1, since centralised control will generally provide improved performance(for example with reduced contention). Furthermore, in somecircumstances there may be terminal devices undertaking D2Dcommunications while they are in an area of poor coverage, for exampleat a cell edge. In this respect the terminal devices may be able toreceive some communications from the base station, for example systeminformation broadcasts, but may not be able to reliably receive otherroutine communications, for example resource allocation signalling. Inthis scenario the terminal devices may operate according to Mode 2, butnonetheless receive some configuration information from the base stationregarding the overall resources available for supporting D2Dcommunications in the wireless telecommunications system.

It is expected that D2D communications within a cell served by a basestation will be restricted to a subset of transmission resources (interms of times and/or frequency) selected from the overall range oftransmission resources available in the cell. Furthermore, it isexpected for some implementations the restricted subset of transmissionresources available for supporting D2D communications (e.g. the radiocommunication link 514 in FIG. 5) will not be available for supportingconventional uplink/downlink signalling (e.g. the radio communicationlinks 510, 512 in FIG. 5). In this regard the set (pool) of resources tobe made available for supporting D2D communications may be considered asbeing reserved for D2D communications.

Thus to summarise, a portion of the transmission resources (e.g. one ormore blocks of time and/or frequency) that would otherwise be availablefor communications between a base station and terminal devices may beused for communications directly between terminal devices in accordancewith a device-to-device operating mode. The specific resources that maybe used for D2D communications, e.g. in terms of time and frequencyresources, within a given wireless telecommunications system may comefrom within the range of frequencies assigned for conventional uplink ordownlink resources. However, as noted above, it is more likely that D2Dcommunications will make use of radio resources within the host wirelesstelecommunications system's uplink resources. The manner in which theresources available for D2D are spread throughout the communicationcell's overall operating bandwidth may be different in differentimplementations. In some cases the pool of resources that may be usedfor D2D communications may be contiguous in time and frequency (e.g.corresponding to a continuous band of resources within a frame structuresuch as represented in FIG. 2B, for example). In other cases the pool ofresources for supporting D2D communications may be non-contiguous intime and/or frequency. For example, in one implementation thetransmission resources available for D2D communications may comprise acontinuous band of frequencies within the overall cell bandwidth, butD2D communications may not be available in every (sub)frame. In anotherexample, the D2D communications may be supported in every subframe, butmay use non-contiguous frequencies. More generally, the specificarrangement of transmission resources available for D2D communicationsin terms of absolute times and frequencies is not significant. For easeof explanation the embodiments described herein will assume there is acontiguous time and resource grid available for D2D communications, butin some respects this may be considered to represent a logicallycontiguous baseband arrangement, while the actual arrangement of radioresources in terms of absolute time and frequency elements may benon-contiguous.

It will be appreciated the specific nature of the physical layersignalling and protocols adopted for D2D communications is notsignificant to the principles of operation described herein. It will beassumed here that D2D communications are based on a radio framestructure comprising blocks of time and frequency resourcescorresponding to those used for downlink communications in aconventional LTE system (e.g. based on the principles represented inFIGS. 2 and 3). However, in other implementations different framestructures may be employed.

Thus, D2D communications can allow terminal devices operating in awireless telecommunications system to communicate directly with oneanother, and this can be regardless of whether or not the terminaldevices are within the coverage area of a base station operating in thewireless telecommunications system. As discussed above, this can allowdata to be more efficiently communicated from one terminal device toanother (because there is no need for the data to be separatelytransmitted in uplink and then again in downlink).

Furthermore, because the terminal devices can communicate even whenthere is no network coverage, device-to-device operating modes can bewell-suited to application such as public safety communications, forexample. This is because D2D communications between terminal devices,for example terminal devices associated with emergency responders, cancontinue to communicate with each other in congested networks and whenoutside a coverage area (for example because of network failure).

In order to improve data rates (for example to support video streaming)between terminal devices, or to improve communication reliability bycombining multiple transmissions of the same data, one option for a D2Dcontext would be to utilise multiple carrier operation. That is to say,a device-to-device communications link between a first terminal deviceand a second terminal device may be configured to make use of two (ormore) logical carriers. This may be particularly beneficial inbroadcast-scenarios in which a single terminal device transmits data forreception by a plurality of receiving terminal devices in adevice-to-device operating mode.

To help support multiple-carrier operation in a D2D context, certainembodiments of the disclosure propose an arrangement in which a firstterminal device may transmit data to a second terminal device in adevice-to-device communication mode in a wireless telecommunicationssystem supporting communications on a first carrier operating over afirst frequency band (F1) and a second carrier operating over a secondfrequency band (F2). In accordance with certain embodiments of thedisclosure, the first terminal device may communicate user-plane data(higher-layer data) using both carriers based on control signallingcomprising scheduling assignment information transmitted on one of thecarriers. Such scheduling announcement control signalling may also bereferred to as side-link control signalling. In an LTE context,scheduling announcements/side-link control signalling may broadly beseen as a D2D equivalent of PDCCH resource allocation signalling.

This approach can be advantageous in certain implementations for anumber of reasons. For example, in some implementations it can reducethe overall amount of control signalling required to supportmulticarrier D2D operation. This can be important because in some D2Dimplementations there may be restrictions on the radio resourcescomprising the respective carriers which the terminal devices may usefor D2D communications, for example to facilitate coexistence withconventional communications between a base station and terminal devicesoperating on the same carrier frequencies. It can therefore be importantto use the resources available for D2D communications as efficient aspossible. In particular, in a scenario in which there may be arelatively large number of separate device-to device communications, itcan be important to make efficient use of the radio resources availablefor control signalling to avoid a situation in which there might beradio resources available for transmitting user-plane data, butinsufficient resources for the control signalling needed to allocatethese radio resources for use.

Thus, in accordance with certain embodiments of the disclosure, D2Dscheduling announcement signalling (control signalling) transmitted onone carrier may provide an indication of radio resources on bothcarriers to be used for user-plane (higher-layer) data. This can beachieved in several ways, and some examples are discussed further below.

In accordance with some other embodiments of the disclosure, D2Dscheduling announcement signalling (side-link control signalling)transmitted on one carrier may provide an indication of radio resourceson the other carrier, without providing an indication of radio resourceson the carrier in which the control signalling is sent. Although thisapproach does not take maximum advantage of the higher throughputavailable for user-plane by using multiple carriers, it can nonethelessbe a useful approach in some scenarios. For example, in a multicarrierD2D context a transmitting terminal device may be free to select fromany of the carriers for transmitting user-plane data, for example basedon resource availability. However, it can nonetheless be helpful for thetransmitting terminal device to communicate its scheduling announcementson only one of the carriers. This is so that a receiving terminal deviceneeds only monitor one carrier to identify when D2D transmissions are tobe made to the receiving device. This can be particularly relevant forterminal devices which are only able to receive a single carrier anygiven time. Likewise, some wireless telecommunications systems mayprovide a dedicated carrier for communicating public-safety related D2Duser-plane data that is separate from a carrier used for routinecommunications. In this case it can be beneficial for the carrier forroutine communications to provide side-link control signalling relatingto the dedicated public-safety related carrier to avoid terminal deviceshaving to permanently monitor the dedicated carrier.

Having set out some of the principles underlying certain embodiments ofthe disclosure, some more specific examples of the approaches discussedabove will now be described with reference to FIGS. 6 to 11.

FIG. 6 schematically represents an arrangement of radio resources usedto support D2D communications between the first terminal device 506 andthe second terminal device 508 represented in FIG. 5 in accordance withan embodiment of the disclosure. In this example it is assumed the firstterminal device 506 transmits data to the second terminal device 508 ina D2D operating mode using two logical carriers 601, 602. In this regardit will be appreciated the contents of the data and the reason why thefirst terminal device is transmitting the data to the second terminaldevice in the D2D operating mode are not significant to the principlesunderlying the operating principles described herein. It will further beappreciated that in some implementations the first terminal device maybe involved in transmitting the relevant-data in a broadcast mode. Thatis to say, the data may be transmitted from the first terminal device toa plurality of other terminal devices, of which the second terminaldevice represented in FIG. 5 is only one.

Thus the radio resources are provided by a first logical carrier 601(uppermost in FIG. 6) operating over a first frequency band F1 and asecond logical carrier 602 (lowermost in FIG. 6) operating over a secondfrequency band F2. Each carrier in FIG. 6 comprises an arrangement ofradio resource blocks arranged in time (horizontal direction in thefigure) and frequency (vertical direction in the figure). The specificradio resources comprising the respective carriers (e.g. in terms ofabsolute frequencies) may be established in accordance with conventionalmulticarrier techniques in wireless telecommunications systems, forexample based on which frequencies are available for use by the operatorof the wireless telecommunications system and how the operator of thewireless telecommunications system has chosen to deploy the network onthese frequencies to support D2D operations.

In this example it is assumed the D2D communication mode employs a radioframe structure which broadly corresponds with an LTE-type downlinkradio frame structure (e.g. of the kind represented in FIG. 2B).Accordingly, each of the first and second carriers support a D2D radiointerface having a radio frame structure comprising a plurality of radiosubframes. For each carrier represented in FIG. 6, three subframes areshown, these are labelled in FIG. 6 as SF-A, SF-B and SF-C (these labelswill be taken to apply for all of FIGS. 6 to 10 and 12). It will beappreciated there will in general be more radio subframes to the leftand right of those represented in the figure. In this example thesubframes on each carrier are synchronised in time. That is to say,subframe SF-A on the first carrier 601 and corresponding subframe SF-Aon the second carrier 602 are at the same times, and likewise for theSF-B and SF-C. In this example each subframe comprises a control region603 and a user-plane region 604, and in terms of their functionality,these regions 603, 604 may respectively correspond with PDCCH and PDSCHregions in a conventional LTE downlink subframe (these referencenumerals for the control regions 603 and user-plane regions 604 will betaken to apply for all of FIGS. 6 to 10 and 12). The transmittingterminal device 506 may thus transmit resource allocation signalling inthe control region 603 of a subframe to provide an indication of radioresources in the user-plane data region 604 which are to be used fortransmitting data to the receiving terminal device 508 identified in theresource allocation signalling. In this regard the signalling protocolsused by the transmitting terminal device 506 for allocating radioresources to the receiving terminal device 508 may be generally based onthe same protocols as resource allocation signalling used by a basestations for conventional LTE downlink communications unless modified tosupport embodiments of the present disclosure as described herein. Forexample, the scheduling announcement signalling may be associated with aradio network identifier for the terminal device(s) to which theallocated resources are addressed. However, in general any scheme forcommunicating scheduling assignments in a D2D operating mode may bemodified in accordance the principles described herein.

In the example represented in FIG. 6, the first (transmitting) terminaldevice 506 is configured to operate in a D2D mode to transmit data tothe second (receiving) terminal device 508 on the first carrier, andthis may be generally in accordance with previously proposed techniquesfor D2D operations, but the allocation of radio resources provided bycontrol signalling transmitted in the control region 603 of the firstcarrier 601 is taken to apply also to the second carrier 602.

Thus, in subframe SF-A, the transmitting terminal device 506 transmitscontrol signalling 606A comprising a scheduling announcement (side-linkcontrol signalling) indicating radio resources 608A in the user-planeregion 604 of the subframe SF-A on which data is to be transmitted tothe receiving terminal device 508. In this example it is assumed thecontrol signalling 606A indicates three separate regions of radioresources 608A in the user-plane region 604. This allocation isschematically indicated by the arrows in the figure. However, it will beappreciated the specific radio resources (i.e. in terms of specific timeand frequency resource blocks) indicated by the control signalling isnot significant and may be based on established principles of schedulingD2D transmissions in a wireless telecommunications systems in asingle-carrier context.

However unlike a conventional D2D operating mode, and as noted above, inaccordance with the example represented in FIG. 6, both the transmittingterminal device 506 and the receiving terminal device 508 are configuredto interpret the control signalling 606A as applying to both theuser-plane region 604 of the first carrier 601 in subframe SF-A and theuser-plane region 604 of the second carrier 602 in the subframe SF-A.Thus, the control signalling 606A sent on the first carrier provides animplicit indication of radio resources 610A in the user-plane region ofthe second carrier, as schematically indicated by the shaded blocksrepresented in FIG. 6. Thus, the transmitting terminal device 506 havingtransmitted the control signalling 606A to the receiving terminal deviceon the first carrier may then transmit user-plane data to the secondterminal device using both the radio resources 608A on the first carrier601 and the radio resources 610A on the second carrier 602. Thetransmission of data on the allocated radio resources may in itself beperformed in any conventional D2D manner. Thus, the receiving terminaldevice having received the control signalling 606A on the first carriermay simply proceed to receive and decode the user-plane data in both theradio resources 608A on the first carrier and the radio resources 610Aon the second carrier. A similar process occurs in subframes SF-B andSF-C. Thus in subframe SF-B control signalling 606B indicating radioresources 608B for communicating user-plane data on the first carrieralso provides an indication of corresponding radio resources 610B forcommunicating user-plane data on the second carrier. Likewise, insubframe SF-C control signalling 606C indicating radio resources 608Cfor communicating user-plane data on the first carrier also provides anindication of radio resources 610C for communicating user-plane data onthe second carrier.

Thus, in accordance with the approach represented in FIG. 6, the controlsignalling overhead associated with allocating radio resources on thefirst and second carriers is in effect halved.

In this particular example the transmitting and receiving terminaldevices are configured to assume the same arrangement of resources inthe corresponding subframes of the respective carriers. That is to saythe pattern of radio resources 608A in subframe SF-A is the same as thepattern of radio resources 610A in subframe SF-A (i.e. the time andfrequency resource blocks are at the same relative locations within eachcarrier). However, it will be appreciated that in other implementationsthe radio resources 610A on the second carrier indicated by the controlsignalling 606A on the first carrier need not be at the same relativelocations as the radio resources 608A on the first carrier. For example,the first and second terminal devices may be configured to modify theradio resources indicated by the control signalling 606A when applied tothe second carrier in accordance with a predefined scheme. For example,the terminal devices may be configured to assume the radio resources610A on the second carrier are offset in time by a pre-defined amountrelative to the radio resources 608A on the first carrier indicated bythe control signalling 606A.

In this regard, the approach represented in FIG. 6 is one in which theindication of radio resources on the second carrier to be used forcommunicating user-plane data is provided implicitly by the controlsignalling 606A transmitted on the first carrier.

Configuration aspects of the approach represented in FIG. 6, such as thecarriers to which the scheduling announcement signalling is applicable,may be established through prior signalling, for example systeminformation signalling, or predefined in accordance with an operatingstandard of the wireless telecommunications system. In some cases thescheduling announcement signalling 606A may itself include an indicationof whether or not the resource allocations are to be applied to othercarriers, and if so which carriers. This provides the transmittingterminal device with a simple mechanism for in effect activating anddeactivating the use of the second carrier on a subframe-by-subframebasis.

As noted above, the content of the data transmitted on the first andsecond carriers is not significant to the operating printable describedherein. In some cases the data transmitted on the two carriers may bedifferent, thereby providing increased throughput. In other cases thedata transmitted on the two carriers may be the same such that thereceiving terminal device can combine the received signalling to seek toimprove reliability in respect of the communications. In certainimplementations the control signalling may include an indication as towhether or not the data transmitted on the two carriers is the same ordifferent in respect of a given subframe, or this may be configuredsemi-statically, for example through system information signalling.

FIG. 7 schematically represents an arrangement of radio resources usedto support D2D communications between the first terminal device 506 andthe second terminal device 508 represented in FIG. 5 in accordance withanother embodiment of the disclosure. FIG. 7 is generally similar to,and will be understood from, FIG. 6, and aspects of FIG. 7 whichcorrespond directly with aspects of FIG. 6 discussed above are notdescribed again in detail in the interest of brevity. The approachrepresented in FIG. 7 differs from the approach represented in FIG. 6 inthat the control signalling on one carrier provides an explicitindication of radio resources to be used for user-plane data on anothercarrier (as opposed to providing an implicit indication as in theapproach of FIG. 6).

Thus, in subframe SF-A represented in FIG. 7, the transmitting terminaldevice 506 transmits control signalling 706A on the first carrier 701which comprises side-link control signalling indicating radio resources708A in the user-plane region 604 of the subframe SF-A on the firstcarrier 701 and also radio resources 710A in the user-plane region 604of the subframe SF-A on the second carrier 702. The radio resources708A, 710A may then be used for transmitting user-plane data to theterminal device(s) to which the side-link control signalling isaddressed. In this example it is assumed the control signalling 706Aindicates three separate regions of radio resources 708A in theuser-plane region 604 of the first carrier 701 and three separatecontrol regions of radio resources 710A in the user-plane region 604 ofthe second carrier 702, as schematically indicated by the arrows in thefigure. The manner in which the control signalling 706A indicates theradio resources 710A on the second carrier may broadly correspond withthe manner in which control signalling might normally indicate allocatedradio resources in a single-carrier D2D context, but with a modificationto include an indication in association with each resource allocation toindicate the carrier to which the resource allocation applies, forexample based on indexing.

Thus, in the approach of FIG. 7 the control signalling 706A sent on thefirst carrier provides an explicit indication of radio resources 710A inthe user-plane region of the second carrier 702 in addition to anexplicit indication of radio resources 708A in the user-claim region ofthe first carrier 701. The transmitting terminal device 506 havingtransmitted the control signalling 706A to the receiving terminal device508 on the first carrier may then transmit user-plane data to the secondterminal device using both the radio resources 708A on the first carrier701 and the radio resources 710A on the second carrier 702. A similarprocess occurs in subframes SF-B and SF-C of FIG. 7. Thus in subframeSF-B control signalling 706B indicating radio resources 708B forcommunicating user-plane data on the first carrier 701 also provides anindication of radio resources 710B for communicating user-plane data onthe second carrier 702. Likewise, in subframe SF-C control signalling706C indicating radio resources 708C for communicating user-plane dataon the first carrier also indicates radio resources 710C forcommunicating user-plane data on the second carrier.

Thus, the approach represented in FIG. 7 is broadly similar to theapproach of FIG. 6, except the indication of radio resources on thesecond carrier to be used for communicating user-plane data is providedexplicitly (as opposed to implicitly) in the control signalling 706Atransmitted on the first carrier. This approach involves a modificationto the control signalling format and also provides a slight increase inthe overall amount of control signalling as compared to the approach ofFIG. 6, but the approach of FIG. 7 can provide greater flexibility inhow the radio resources are allocated for use by the first terminaldevice across the two carriers.

FIG. 8 schematically represents an arrangement of radio resources usedto support D2D communications between the first terminal device 506 andthe second terminal device 508 represented in FIG. 5 in accordance withanother embodiment of the disclosure. FIG. 8 is generally similar to,and will be understood from, FIG. 6, and aspects of FIG. 8 whichcorrespond directly with aspects of FIG. 6 discussed above are notdescribed again in detail in the interest of brevity. However, theapproach represented in FIG. 8 differs from the approach represented inFIG. 6 in that in addition to providing control signalling on the firstcarrier to indicate radio resources allocated for user-plane data on thesecond carrier, there is also provided control signalling on the secondcarrier to indicate radio resources allocated for user-plane data on thefirst carrier.

Thus, in subframe SF-A in FIG. 8, the transmitting terminal device 506transmits control signalling 806A comprising side-link controlsignalling on the first carrier 801. The control signalling 806A on thefirst carrier 801 provides an explicit indication of radio resources806A in subframe SF-A on the first carrier 801 and an implicitindication of radio resources 810A in subframe SF-A on the secondcarrier 802. In this regard the operation of the example embodimentrepresented in FIG. 8 in using control signalling on one carrier toprovide an implicit indication of radio resources on another carrier maycorrespond with the operation described above with respect to FIG. 6.

However, in subframe SF-A in FIG. 8, the transmitting terminal device506 also transmits control signalling 812A comprising side-link controlsignalling on the second carrier 802. The control signalling 812A on thesecond carrier 802 provides an explicit indication of radio resources810A in subframe SF-A on the second carrier 802 and an implicitindication of radio resources 806A in subframe SF-A on the first carrier801. In this regard the operation of the example embodiment representedin FIG. 8 corresponds with the operation described above with respect toFIG. 6 but with the carriers reversed.

A similar process occurs in subframes SF-B and SF-C of FIG. 8. Thus insubframe SF-B, control signalling 806B on the first carrier 801 andcontrol signalling 812A on the second carrier 802 both indicateresources 808B, 810B on both the first and second carriers. Likewise, insubframe SF-C, control signalling 806C on the first carrier and controlsignalling 812C on the second carrier both indicate resources 808C, 810Con both the first and second carriers.

The advantage of this approach over the approach of FIG. 6 is the dualtransmission of control signalling indicating radio resources on bothcarriers. This means that if a receiving terminal device fails toreceive the control signalling on one of the carriers, it maynonetheless receive the control signalling on the other carrier, andfrom this determine the radio resources 808A, 810A for user-plane dataon both carriers. This provides a level of redundancy in the controlsignalling transmissions. This may be useful, for example, where thereis a concern the control signalling may not be received with a highdegree of reliability. As with the other example embodiments describedherein, the configuration of this operation may be established throughsystem information or an indication that the control signalling appliesto more than one carrier may be included with the control signallingitself. Furthermore, a receiving terminal device may combine the controlsignalling 806A, 812A received on the first and second carriers to helpimprove the likelihood of successful receipt.

Although FIG. 8 is presented in the context of a modified version of theapproach of FIG. 6 in which the indication of an allocation of radioresources on one carrier is implicitly provided by control signalling onanother carrier, a similar modification can be applied to the approachof FIG. 7. That is to say, for an approach in which control signallingon one carrier provides an explicit indication of radio resourceallocations on multiple carriers, more than one of the multiple carriersmay in some implementations include control signalling providingexplicit indications of the radio resource allocations on the differentcarriers.

FIG. 9 schematically represents an arrangement of radio resources usedto support D2D communications between the first terminal device 506 andthe second terminal device 508 represented in FIG. 5 in accordance withanother embodiment of the disclosure. FIG. 9 is generally similar to,and will be understood from, FIG. 7. However, the approach representedin FIG. 9 differs from the approach represented in FIG. 7 in that theradio resources allocated for user-plane data transmissions on the twocarriers are time-multiplexed. That is to say, the transmitting terminaldevice is arranged to schedule the user-plane transmissions on the twocarriers for non-overlapping times. This may be appropriate, forexample, in a situation in which a receiving terminal device is unableto receive signalling on multiple carriers at the same time. Althoughthis approach does not in itself provide for greater throughput, itprovides greater scheduling flexibility. For example, it allows thetransmitting terminal device to select from among a wider range of radioresources for transmitting user-plane data whilst the receiving terminaldevice need only monitor for control signalling on one carrier. It willbe appreciated in some cases there may be further restrictions appliedwith regards to the timings of the radio resource allocations foruser-plane data according to the operating capabilities of the terminaldevices. For example, as well as not overlapping in time, the radioresources on the two carriers may be separated in time by an amountsufficient to allow the receiving terminal device (and/or thetransmitting terminal device) time to retune its transceiverappropriately.

A similar process occurs in subframes SF-B and SF-C of FIG. 9. Thus insubframe SF-B control signalling 906B indicating radio resources 908Bfor communicating user-plane data on the first carrier 901 also providesan indication of radio resources 910B for communicating user-plane dataon the second carrier 902 for different times. Likewise, in subframeSF-C control signalling 906C indicating radio resources 908C forcommunicating user-plane data on the first carrier also indicatesnon-overlapping radio resources 910C for communicating user-plane dataon the second carrier.

FIG. 10 schematically represents an arrangement of radio resources usedto support D2D communications between the first terminal device 506 andthe second terminal device 508 represented in FIG. 5 in accordance withanother embodiment of the disclosure. FIG. 10 is generally similar to,and will be understood from, FIG. 6, and aspects of FIG. 10 whichcorrespond directly with aspects of FIG. 6 discussed above are notdescribed again in detail in the interest of brevity. In the approach ofFIG. 6 the indication of radio resources on the second carrier 602provided by the control signalling 606 transmitted on the first carrier602 is considered to apply for all subframes. However, in the approachof FIG. 10, control signalling transmitted on one carrier is associatedwith an indication of which carrier(s) the control signalling appliesfor, in this example on a subframe-by-subframe basis. This indicationmay, for example, be referred to as a carrier-active indicator. Thecarrier-active indicator may comprise a simple binary indicator in theside-link control signalling for each of the carriers to which thecontrol signalling could potentially apply.

In the example of FIG. 10 there are two carriers 1001, 1002, and so atwo-bit carrier-active indicator may be used, for example with a firstdigit referring to the first carrier 1001 and a second digit referringto the second carrier. For each digit of the carrier-active indicator avalue of “0” may be taken to indicate the associated control signallingdoes not apply for that carrier (carrier inactive for that subframe)whereas a value of “1” may be taken to indicate the associated controlsignalling does apply for that carrier (carrier active for thatsubframe).

Thus, in subframe SF-A in FIG. 10, the transmitting terminal device 506transmits control signalling 1006A comprising side-link controlsignalling on the first carrier 1001. The control signalling 1006A onthe first carrier 1001 identifies radio resources 1006A in subframe SF-Aon the first carrier 1001 and also radio resources 1010A in subframeSF-A on the second carrier 1002 as in the manner described above for theapproach of FIG. 6. However, the control signalling 1006A in FIG. 10 isassociated with an indication as to whether or not the identified radioresources are to be used for each of the carriers 1001, 1002. Asmentioned above, this carrier-active indicator may be provided as asimple binary indicator for each carrier and example values for thecarrier-active indicator are shown in association with the controlsignalling represented in FIG. 10 for each subframe. The indication maybe provided, for example, as a new information element in the controlsignalling 1006A.

Thus, in subframe SF-A the carrier-active indicator value of “11”indicates the radio resources identified on the first and secondcarriers by control signalling 1006A are both being used for thatsubframe. Thus, the transmitting terminal device proceeds to transmituser-plane data in the radio resources 1008A on the first carrier 1001and the radio resources 1010A on the second carrier 1002 and thereceiving terminal device seeks to receive these transmissions.

However, in subframe SF-B the carrier-active indicator value of “10” incontrol signalling 1006B indicates the identified radio resources areonly being used on the first carrier 1001 for this subframe. Thus, thetransmitting terminal device transmits user-plane data in the radioresources 1008B on the first carrier 1001 but does not transmit any dataon the radio resources 1010B on the second carrier 1002 in subframeSF-B.

In subframe SF-C the carrier-active indicator value of “01” in controlsignalling 1006C indicates the identified radio resources are only beingused on the second carrier 1002 for the subframe.

Thus, the transmitting terminal device transmits user-plane data on theradio resources 1010C on the second carrier 1002 but does not transmitany data on the radio resources 1008C on the first carrier 1001 insubframe SF-C.

Thus the approach of FIG. 10 provides for further flexibility over theapproach of FIG. 6 in that the transmitting terminal device can decide(and indicate to the receiving terminal device(s)) on asubframe-by-subframe basis whether transmissions on multiple carriersare being used for that subframe, and if so, which of the availablecarriers are to be used.

Thus, the approaches described above with reference to FIGS. 6 to 10provide mechanisms for flexibly using multiple carriers in adevice-to-device communication mode by providing indications of radioresources on one carrier in control signalling transmitted on anothercarrier.

FIG. 11 is a ladder diagram schematically representing signallingexchange between the terminal devices 506, 508 schematically representedin FIG. 5 in accordance with certain embodiments of the disclosure suchas discussed above, for example with reference to FIGS. 6 to 10. It isassumed here the terminal devices 506, 508 are exchanging D2Dcommunications, with the terminal device 506 transmitting and theterminal device 508 receiving. In this regard the terminal device 506may be referred to as the transmitting terminal device (UE “T”) whilethe terminal device 508 may be referred to as the receiving terminaldevice (UE “R”).

In Step S1 the transmitting terminal device 506 identifies that there is(or will be) user-plane to transmit to the receiving terminal device ina D2D communication mode. The reason why the data is to be transmittedfrom the transmitting terminal device to the receiving terminal deviceis not significant. For example, it may be that the first and secondterminal devices are operating in a walkie-talkie device-to-devicecommunication mode, and the user of the first terminal device haspressed a “transmit” button.

In Step S2 the transmitting terminal device 506 selects radio resourceson the first and second carriers (and possibly others if there are morethan two carriers that may be used) to use for transmitting the userplane data that is to be transmitted. The transmitting terminal devicemay select these resources taking account of conventional principles forscheduling data transmissions, bearing in mind the availability of radioresources on multiple carriers in accordance with embodiments of thedisclosure.

In Step S3 the transmitting terminal device 506 transmit controlsignalling (scheduling announcement signalling/side-link controlsignalling) to the receiving terminal device 508. This signallingprovide an indication of the radio resources on the first and secondcarriers selected for transmitting the user-plane data. In terms ofsignalling protocols, this control signalling may be communicatedgenerally in accordance with conventional techniques for exchangingcontrol information in a device-to-device communication mode.

In Step S4 the transmitting terminal device proceeds to transmit theuser plane data on the scheduled resources on the first and secondcarriers and the data are received by the receiving terminal device. Interms of signalling protocols, these communications may be performedgenerally in accordance conventional techniques for exchanging data in adevice-to-device communication mode, albeit using resources frommultiple carriers in accordance with embodiments of the disclosure.

As noted above, in particular with reference to FIGS. 6 to 11, certainembodiments of the disclosure help to support multiple-carrier operationin a D2D context by providing control signalling on one carrier whichindicates radio resources to be used for communicating data on anothercarrier. However, in addition to this, or separately and independentlyfrom this, there are approaches in accordance with other embodiments ofthe disclosure which help to support multiple-carrier operation in a D2Dcontext in other ways.

For example, certain other embodiments of the disclosure propose anarrangement in which a first terminal device may transmit data to asecond terminal device in a device-to-device communication mode in awireless telecommunications system supporting communications on a firstcarrier operating over a first frequency band (F1) and a second carrieroperating over a second frequency band (F2). In such a scenario, thefirst terminal device may be communicating with the second terminaldevice on the first carrier in a device-to-device communication mode,but may determine that it would be more appropriate to switch thesecommunications to the second carrier, for example because of changes inresource availability. Therefore, the transmitting terminal device maytransmit control signalling on the first carrier that is addressed tothe second terminal device and which comprises an indication that thefirst terminal device intends to transmit data to the second terminaldevice in a device-to-device communication mode on the second carrierfollowing a carrier switch-over time. The first terminal device may thenproceed with communicating with the second terminal device on the secondcarrier after the carrier switch-over time. In this regard to theindication may be referred to as a carrier switch indication. Thecarrier switch indication may in some cases be conveyed in associationwith control signalling comprising scheduling assignment information forthe first carrier.

This approach to supporting multicarrier D2D operation can beadvantageous in providing a ready mechanism for a transmitting terminaldevice to switch operation from one carrier to another carrier, forexample in response to changing traffic conditions. In someimplementations one carrier may in effect be considered a “default”carrier which terminal device(s) that might receive device-to-devicecommunications routinely monitor. Then, if there is device-to-deviceuser-plane data to be communicated to a receiving terminal device, thereceiving terminal device may be directed to switch to another carrieron which the user-plane data is transmitted. In principle the firstcarrier might not be used for communicating any user-plane data in adevice-to-device operating mode, but may only be used for indicating toterminal devices when they needs to switch to another carrier to receiveD2D user-plane data. This approach might be adopted, for example, in ascenario in which a wireless telecommunications system provides a firstcarrier primarily for conventional communications between a base stationand a terminal device and a second carrier primarily fordevice-to-device communications. For example, a dedicateddevice-to-device carrier may be provided to ensure high reliability andgood availability in respect of device-to device communications whenthey are needed, for example in an emergency/public safety context.Thus, the receiving terminal device(s) need only monitor for controlsignalling on the first carrier that they may already be monitoring forconventional communications from the base station to identify when thereis a need to switch to the second carrier to receive device-to-devicecommunications.

Thus, in accordance with certain embodiments of the disclosure, D2Dcontrol signalling transmitted on one carrier may provide an indicationthat a receiving terminal device should switch to another carrier toreceive further D2D data.

FIG. 12 schematically represents an arrangement of radio resources usedto support D2D communications between the first terminal device 506 andthe second terminal device 508 represented in FIG. 5 in accordance withan embodiment of the disclosure. In this example it is assumed the firstterminal device 506 transmits data to the second terminal device 508 ina D2D operating mode using two logical carriers 1201, 1202. In thisregard it will be appreciated the contents of the data and the reasonwhy the first terminal device is transmitting the data to the secondterminal device in the D2D operating mode are not significant to theprinciples underlying the operating principles described herein. It willfurther be appreciated that in some implementations the first terminaldevice may be involved in transmitting the relevant-data in a broadcastmode. That is to say, the data may be transmitted from the firstterminal device to a plurality of other terminal devices, of which thesecond terminal device represented in FIG. 5 is only one.

Thus the radio resources are provided by a first logical carrier 1201(uppermost in FIG. 12) operating over a first frequency band F1 and asecond logical carrier 1202 (lowermost in FIG. 12) operating over asecond frequency band F2. Each carrier in FIG. 12 comprises anarrangement of radio resource blocks arranged in time (horizontaldirection in the figure) and frequency (vertical direction in thefigure). The specific radio resources comprising the respective carriers(e.g. in terms of absolute frequencies) may be established in accordancewith conventional multicarrier techniques in wireless telecommunicationssystems, for example based on which frequencies are available for use bythe operator of the wireless telecommunications system and how theoperator of the wireless telecommunications system has chosen to deploythe network on these frequencies to support D2D operations.

In this example it is assumed the D2D communication mode employs a radioframe structure which broadly corresponds with an LTE-type downlinkradio frame structure (e.g. of the kind represented in FIG. 2B).Accordingly, each of the first and second carriers support a D2D radiointerface having a radio frame structure comprising a plurality of radiosubframes. For each carrier represented in FIG. 12, three subframes areshown, these are labelled in FIG. 12 as SF-A, SF-B and SF-C. It will beappreciated there will in general be more radio subframes to the leftand right of those represented in the figure. In this example thesubframes on each carrier are synchronised in time. That is to say,subframe SF-A on the first carrier 1201 and corresponding subframe SF-Aon the second carrier 1202 are at the same times, and likewise for theSF-B and SF-C. In this example each subframe comprises a control region603 and a user-plane region 604, and in terms of their functionality,these regions 603, 604 may respectively correspond with PDCCH and PDSCHregions in a conventional LTE downlink subframe. The transmittingterminal device 506 may thus transmit resource allocation signalling inthe control region 603 of a subframe to provide an indication of radioresources in the user-plane data region 604 which are to be used fortransmitting data to the receiving terminal device 508 addressed by theresource allocation signalling. In this regard the signalling protocolsused by the transmitting terminal device 506 for allocating radioresources to the receiving terminal device 508 may be generally based onthe same protocols as resource allocation signalling used by a basestations for conventional LTE downlink communications unless modified tosupport embodiments of the present disclosure as described herein. Forexample, the scheduling announcement signalling may be associated with aradio network identifier for the terminal device(s) to which theallocated resources are addressed. However, in general any scheme forcommunicating scheduling assignments in a D2D operating mode may bemodified in accordance the principles described herein.

In the example represented in FIG. 12, the first (transmitting) terminaldevice 506 is configured to operate in a D2D mode to transmit data tothe second (receiving) terminal device 508 on the first carrier, andthis may be generally in accordance with previously proposed techniquesfor D2D operations, but the transmitting terminal device 506 is alsoconfigured to provide an indication to the second terminal device thatit should seek to receive transmissions from the first terminal deviceon the second carrier following a carrier switch-over time. In theexample represented in FIG. 12 it will be assumed the transmittingterminal device communicates with the receiving terminal device on thefirst carrier 1201 in subframes SF-A and SF-B, but has determined thatin subframe SF-C, it should instead communicate with the second terminaldevice on the second carrier 1202. That is to say, the carrierswitch-over time in this example is between subframes SF-B and SF-C. Thespecific reason why the transmitting terminal device determines that itshould switch to communicating with the second terminal device in adevice-to-device mode on the second carrier starting from subframe SF-Cis not significant. For example, it may be that the transmittingterminal device has recognised a change in traffic conditions, forexample relating to congestion or interference, on the carriers meansthat its communications would be more suitably made on the secondcarrier, or because a certain carrier may be prioritised for certaincommunications.

From the perspective of a terminal device, carrier switching may beimportant in some situations because of issues relating to terminaldevice capability/complexity. For example, carrier switching may beparticularly suitable for situations in which a transmitting orreceiving terminal device does not have dual RF carrier/basebandcapability.

In terms of a transmitter side terminal device, two transmitter modules(i.e. two power amplifier/separate RF transceiver functions) would allowthe terminal device to support simultaneous multi-carrier D2Dtransmissions. However, there can be significant cost and complexityissues in providing two transmitter (Tx) modules. In accordance with theprinciples described herein, a transmitting terminal device having onetransmitter module may switch between carriers to in effect operate as amulti-carrier device taking in to account the switching time (withoutsimultaneous operation on both carriers).

In terms of a receiver side terminal device, the D2D receiver may havetwo receivers, one is for out-of-coverage scenarios and the other is forin-coverage scenarios. That is to say, a terminal device may have oneTx/Rx transceiver for an in-coverage carrier and another Tx/Rxtransceiver for an out-of-coverage carrier—i.e. a total two Tx/Rxtransceivers. The resource allocations for the in-coverage situation areunder base station control. If the base station schedules side-linkcontrol signalling resources in both first carrier of out-of-coverageand the second carrier of out-of-coverage, the terminal device maytemporarily switch its in-coverage receiver to support a second out-ofcoverage carrier. After transmitting/receiving data in theout-of-coverage second carrier, the terminal device may switch back tothe in-coverage carrier.

Scheduling decisions may take account of the terminal devices'capability regarding dual Tx/RX and select appropriate scheduling toallow time for carrier switching.

Thus, in subframe SF-A, the transmitting terminal device 506 transmitscontrol signalling 1206A comprising a scheduling announcement (side-linkcontrol signalling) indicating radio resources 1208A in the user-planeregion 604 of the subframe SF-A on which data is to be transmitted tothe receiving terminal device 508. In this example it is assumed thecontrol signalling 1206A indicates three separate regions of radioresources 1208A in the user-plane region 604. This allocation isschematically indicated by the arrows in the figure. However, it will beappreciated the specific radio resources (i.e. in terms of specific timeand frequency resource blocks) indicated by the control signalling isnot significant and may be based on established principles of schedulingD2D transmissions in a wireless telecommunications systems in asingle-carrier context. This aspect of the operation may beconventional.

In accordance with this example implementation, it is assumed thatduring subframe SF-A the transmitting terminal device recognises that itwould be appropriate to switch its device-to-device transmissions to thesecond terminal device to the second carrier. As already mentioned, thespecific reason why this is determined to be appropriate is notsignificant to the principles underlying approaches in accordance withembodiments of the disclosure.

Thus, in subframe SF-B, the transmitting terminal device 506 transmitsto the receiving terminal device on the first carrier 1201 controlsignalling 1206B which contains an indication SW that the transmittingterminal device intends to switch its transmissions to the secondcarrier from a carrier switch-over time. In this example implementationsthe carrier switch-over time is assumed to be the start of the subframefollowing that in which the carrier switch indication SW iscommunicated. In some examples the carrier switch-over time may bedelayed by one or more further subframes, for example to allow time forthe transmitting and all receiving terminal device to retune/reconfiguretheir transceiver circuitry. For example, the transmitting terminaldevice may be configured not to make transmissions on the second carrieruntil at least a certain time has elapsed after the end of thesubcarrier in which the carrier switch indicator was transmitted.

The carrier switch indication SW may, for example, comprise a simplebinary indicator in what might otherwise be conventional controlsignalling (if there are multiple potential carriers to switch to, theindicator may indicate which carrier to switch to). Thus the controlsignalling 1206B may comprise a carrier switch indication andinformation corresponding to a conventional scheduling announcementindicating radio resources 1208B in the user-plane region 604 of thesubframe SF-B on which data is to be transmitted to the receivingterminal device 508. That is to say, the transmitting terminal devicemay continue to transmit data to the receiving terminal device on thefirst carrier in the subframe in which the indication that a carrierswitch is to be made is transmitted. In principle, in someimplementations the presence of the switch indicator SW in the controlregion 602 of subframe SF-B may be taken to indicate the carrierswitchover should happen immediately whereby any resource allocationsassociated with the control signalling received on the first carrier inthe subframe containing he switch indication should be taken to apply tothe second carrier.

Thus, having transmitted the indication of the carrier switch to thesecond terminal device in subframe SF-B, in subframe SF-C, thetransmitting terminal device 506 transmits on the second carrier 1202control signalling 1212C comprising a scheduling announcement (side-linkcontrol signalling) indicating radio resources 1210C in the user-planeregion 604 of the subframe SF-C on which data is to be transmitted tothe receiving terminal device 508 on the second carrier. In this exampleit is again assumed the control signalling 1212C indicates threeseparate regions of radio resources 1210C in the user-plane region 604,as schematically indicated by the arrows in the figure. However, it willagain be appreciated the specific radio resources (i.e. in terms ofspecific time and frequency resource blocks) indicated by the controlsignalling is not significant and may be based on established principlesof scheduling D2D transmissions in a wireless telecommunications systemsin a single-carrier context. This aspect of the operation may again beconventional.

Thus, in accordance with the approach represented in FIG. 12, controlsignalling associated with D2D communications on one carrier may be usedto provide an indication that at least some future D2D communicationsare to be made using radio resources associated with another carrier.

In addition to providing a carrier switch indication, the controlsignalling may also convey an indication of the carrier switch-over timeafter which communications are to be made on the second carrier. Theindication of the carrier switch-over time may be provided implicitly,e.g. it may be determined from a time associated with when the controlsignalling is transmitted. For example, the carrier switch-over time maybe taken to correspond with the time of the control signalling (to anappropriate degree of temporal resolution, for example with a subframeresolution). This corresponds with the approach represented in FIG. 12in which the switch-over time is at the end of the subframe in which thecontrol signalling is transmitted. However, in other examples there maybe a greater delay, for example the switch-over time may be thebeginning of a subframe that is a predefined subframes after the one inwhich the control signalling is transmitted. Alternatively, the controlsignalling itself may indicate the switch-over time. For example thecontrol signalling may explicitly provide an indication of a subframe inwhich the carrier switch-over is to be made (e.g. by providing anindication of a specific subframe, such as a system frame number, or anumber of subframes to wait after receiving the control signallingbefore switching carrier). It will be appreciated that timings need notbe based on subframes, but there may be other defined periods, forexample windows comprising multiple subframes. The windows maycorrespond with repeat periods for control signalling for D2Dcommunications in an implementation in which D2D communications may notbe available in every subframe. That is to say, the control signallingin some implementations may be repeated on the basis of controlsignalling time windows defined in accordance with a control signallingschedule for the D2D communications associated with the terminal devicerather than on a subframe-by subframe basis.

Following the switch from D2D operations on the first carrier to D2Doperations on the second carrier as represented in FIG. 12, there maysubsequently be a switch back from D2D operations on the second carrierto D2D operations on the first carrier. This switch back may occur inthe same manner as described above, except that the switch indicatorwill be transmitted in control signalling on the second carrier.Conversely, the terminal devices may be configured to switch backautomatically after a predetermined carrier switch-back time.

Such a carrier switch-back time may be based on the characteristics ofthe transmission of data on the second carrier. For example, thetransmitting and receiving terminal devices may be configured toautomatically switch back to operating on the first carrier (i.e. withthe second terminal device monitoring for control signalling on thefirst carrier) if there has been no transmission of data on the secondcarrier for a predefined amount of time.

In some cases an indication of a carrier switch-back time may beprovided in association with the control signalling which initiated thecarrier switch. For example, referring to FIG. 12, the controlsignalling 12068 may further comprise an indication of a carrier switchback time after which operations which is back from the second carrier1202 to the first carrier 1201. The indication of the carrierswitch-back time may be provided implicitly, e.g. it may be determinedfrom a time associated with when the control signalling is transmitted.For example, the carrier switch-back time may be taken to correspondwith a fixed time after the control signalling 12068 that initiated thecarrier switch (with an appropriate degree of temporal resolution, forexample with a subframe resolution). Alternatively, the controlsignalling itself may explicitly indicate a switch-back time. Forexample the control signalling may provide an indication of a specificsubframe in which the carrier switch-back is to be made (e.g. byproviding an indication of a corresponding system frame number or anumber of subframes for which to operate on the second carrier beforeswitching back to the first carrier). It will again be appreciated thattimings need not be based on subframe periods, but may more generally bebased on numbers of control signalling time windows defined inaccordance with control signalling scheduling for the D2Dcommunications.

FIG. 13 is a ladder diagram schematically representing signallingexchange between the terminal devices 506, 508 schematically representedin FIG. 5 in accordance with certain embodiments of the disclosure suchas discussed above with reference to FIG. 12. As before, it is assumedhere the terminal devices 506, 508 are exchanging D2D communications,with the terminal device 506 transmitting and the terminal device 508receiving. In this regard the terminal device 506 may be referred to asthe transmitting terminal device (UE “T”) while the terminal device 508may be referred to as the receiving terminal device (UE “R”).

In Step T1 the first terminal device 506 and the second terminal device508 are communicating in a D2D operating mode on the first carrier. Theprinciples underlying this operating mode may be based on any knownscheme for D2D operations.

In Step T2 the first terminal device determines that it would beappropriate to switch the ongoing D2D operation represented Step T1 fromthe first carrier to the second carrier. This may be, for example,because there is a change in traffic conditions meaning the firstcarrier has become more congested than the second carrier. However, thespecific reason why the first terminal device determines that it shouldswitch operations to the second carrier is not significant.

In Step T3 the transmitting terminal device transmits control signalling(scheduling announcement signalling/side-link control signalling) to thereceiving terminal device 508 which includes an indication that its D2Dtransmissions to the second terminal device are to switch from the firstcarrier to the second carrier. In terms of signalling protocols, thiscontrol signalling may be communicated generally in accordance withconventional techniques for exchanging control information in adevice-to-device communication mode.

As schematically indicated in steps T4 and T5, the transmitting andreceiving terminal devices configure their respective transceivers forD2D operation on the second carrier.

In Step T6 the first terminal device 506 and the second terminal device508 proceed by communicating in a D2D operating mode on the secondcarrier, thus completing the switch in operation from the first carrierto the second carrier.

Although the above-described examples have primarily focused on amulticarrier implementation in which there are two carriers. It will beappreciated that in other implementations that may be more than twocarriers. For example, the side-link control signalling on one carriermay be used to allocate resources for higher-layer data (user-planedata) on two or more other carriers.

Whilst in the above-described embodiments it is assumed the terminaldevices undertaking D2D communications are also able to communicate withother terminal devices via a base station in a conventional non-D2Dmanner, it will be appreciated that in principle a terminal deviceaccording to an embodiment of the disclosure could be a dedicated D2Ddevice that did undertake communications with other terminal devicesthrough a base station.

Although the above-described examples have focused on implementations inthe context of an LTE-based wireless telecommunications system, it willbe appreciated similar principles can be adopted for in wirelesstelecommunications systems operating in accordance with other protocols.

Thus there has been described a method of operating first and secondterminal devices for transmitting data in a device-to-devicecommunication mode in a wireless telecommunications system supportingcommunications on a first carrier operating over a first frequency bandand a second carrier operating over a second frequency band. The firstterminal device transmits control signalling on the first carrier andthis is received by the second terminal device. The control signallingcomprises an indication of an allocation of radio resource blocks on thesecond carrier to be used for transmitting user-plane data from thefirst terminal device to the second terminal device. The first terminaldevice then proceeds to transmit the user-plane data to the secondterminal device on the second carrier using the radio resource blocks onthe second carrier identified by the control signalling. The controlsignalling may also provide an indication of an allocation of radioresource blocks on the first carrier to be used for transmittinguser-plane data to the second terminal device.

Further particular and preferred aspects of the present invention areset out in the accompanying independent and dependent claims. It will beappreciated that features of the dependent claims may be combined withfeatures of the independent claims in combinations other than thoseexplicitly set out in the claims.

Thus, the foregoing discussion discloses and describes merely exemplaryembodiments of the present invention. As will be understood by thoseskilled in the art, the present invention may be embodied in otherspecific forms without departing from the spirit or essentialcharacteristics thereof. Accordingly, the disclosure of the presentinvention is intended to be illustrative, but not limiting of the scopeof the invention, as well as other claims. The disclosure, including anyreadily discernible variants of the teachings herein, define, in part,the scope of the foregoing claim terminology such that no inventivesubject matter is dedicated to the public.

Respective features of the present disclosure are defined by thefollowing two groups of numbered paragraphs:

First Group of Numbered Paragraphs

Paragraph 1. A method of operating a first terminal device fortransmitting data to a second terminal device in a device-to-devicecommunication mode in a wireless telecommunications system supportingcommunications on a first carrier operating over a first frequency bandand a second carrier operating over a second frequency band; the methodcomprising:

transmitting on the first carrier control signalling comprising anindication of radio resources on the second carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device; and

transmitting user-plane data to the second terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

Paragraph 2. The method of paragraph 1, wherein the control signallingfurther comprises an indication of radio resources on the first carrierto be used for transmitting user-plane data from the first terminaldevice to the second terminal device, and wherein the method furthercomprises transmitting user-plane data to the second terminal device onthe first carrier using the radio resources on the first carrierindicated by the control signalling.

Paragraph 3. The method of paragraph 2, wherein the indication of radioresources on the second carrier and the indication of radio resources onthe first carrier are provided by a common indication that is applicableto both carriers.

Paragraph 4. The method of paragraph 2 or 3, wherein the each of thefirst and second carriers operate over a radio interface having a radioframe structure comprising a plurality of radio subframes, and whereincontrol signalling in each radio subframe of the first carrier comprisesan indication of whether the control signalling is providing:

(i) an indication of radio resources on the first carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device; or

(ii) an indication of radio resources on the second carrier to be usedfor transmitting user-plane data from the first terminal device to thesecond terminal device; or

(iii) an indication of radio resources on both the first and secondcarriers to be used for transmitting user-plane data from the firstterminal device to the second terminal device.

Paragraph 5. The method of any of paragraphs 2 to 4, wherein theindication of radio resources on the second carrier and the indicationof radio resources on the first carrier are provided as separateindications.

Paragraph 6. The method of any of paragraphs 2 to 5, wherein each of thefirst and second carriers operate over a radio interface having a radioframe structure comprising a plurality of radio subframes comprisingradio resource blocks arranged in time and frequency, and wherein theindication of radio resources for transmitting user-plane data on thefirst carrier corresponds with a first radio resource block arrangementwithin a subframe of the first carrier and the indication of radioresources for transmitting user-plane data on the second carriercorresponds with a second radio resource block arrangement within asubframe of the second carrier.

Paragraph 7. The method of paragraph 6, wherein the first radio resourceblock arrangement is the same as the second radio resource blockarrangement.

Paragraph 8. The method of paragraph 6, wherein the first radio resourceblock arrangement is not the same as the second radio resource blockarrangement.

Paragraph 9. The method of paragraph 8, further comprising deriving oneof the first and second radio resource block arrangements from the otherof the first and second radio resource block arrangements based on apredefined relationship between them.

Paragraph 10. The method of any of paragraphs 2 to 9, wherein theuser-plane data transmitted to the second terminal device on the secondcarrier is the same as the user-plane data transmitted to the secondterminal device on the first carrier.

Paragraph 11. The method of any of paragraphs 2 to 10, wherein theuser-plane data transmitted to the second terminal device on the secondcarrier is not the same as the user-plane data transmitted to the secondterminal device on the first carrier.

Paragraph 12. The method of any of paragraphs 2 to 11, wherein thecontrol signalling further comprises an indication of whether or not theuser-plane data transmitted to the second terminal device on the secondcarrier is the same as the user-plane data transmitted to the secondterminal device on the first carrier.

Paragraph 13. The method of any of paragraphs 2 to 12, wherein the radioresources on the second carrier indicated by the control signalling arefor times which are different from the times of the radio resources onthe first carrier indicated by the control signalling.

Paragraph 14. The method of any of paragraphs 1 to 13, furthercomprising transmitting on the second carrier control signallingcomprising an indication of the radio resources on the second carrier tobe used for transmitting user-plane data from the first terminal deviceto the second terminal device.

Paragraph 15. A first terminal device for transmitting data to a secondterminal device in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band, wherein the first terminal devicecomprises a controller unit and a transceiver unit configured to operatetogether to

transmit on the first carrier control signalling comprising anindication of radio resources on the second carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device; and

transmit user-plane data to the second terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

Paragraph 16. Circuitry for a first terminal device for transmittingdata to a second terminal device in a device-to-device communicationmode in a wireless telecommunications system supporting communicationson a first carrier operating over a first frequency band and a secondcarrier operating over a second frequency band, wherein the circuitrycomprises a controller element and a transceiver element configured tooperate together to cause the first terminal device to:

transmit on the first carrier control signalling comprising anindication of radio resources on the second carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device; and

transmit user-plane data to the second terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

Paragraph 17. A method of operating a second terminal device forreceiving data from a first terminal device in a device-to-devicecommunication mode in a wireless telecommunications system supportingcommunications on a first carrier operating over a first frequency bandand a second carrier operating over a second frequency band; the methodcomprising:

receiving on the first carrier control signalling comprising anindication of radio resources on the second carrier to be used by thefirst terminal device for transmitting user-plane data to the secondterminal device; and

receiving user-plane data from the first terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

Paragraph 18. The method of paragraph 17, wherein the control signallingfurther comprises an indication of radio resources on the first carrierto be used by the first terminal device for transmitting user-plane datato the second terminal device, and wherein the method further comprisesreceiving user-plane data from the first terminal device on the firstcarrier using the radio resources on the first carrier indicated by thecontrol signalling.

Paragraph 19. The method of paragraph 18, wherein the indication ofradio resources on the second carrier and the indication of radioresources on the first carrier are provided by a common indication thatis applicable to both carriers.

Paragraph 20. The method of paragraph 18 or 19, wherein the each of thefirst and second carriers operate over a radio interface having a radioframe structure comprising a plurality of radio subframes, and whereincontrol signalling in each radio subframe of the first carrier comprisesan indication of whether the control signalling is providing:

(i) an indication of radio resources on the first carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device; or

(ii) an indication of radio resources on the second carrier to be usedfor transmitting user-plane data from the first terminal device to thesecond terminal device; or

(iii) an indication of radio resources on both the first and secondcarriers to be used for transmitting user-plane data from the firstterminal device to the second terminal device.

Paragraph 21. The method of any of paragraphs 18 to 20, wherein theindication of radio resources on the second carrier and the indicationof radio resources on the first carrier are provided as separateindications.

Paragraph 22. The method of any of paragraphs 18 to 21, wherein each ofthe first and second carriers operate over a radio interface having aradio frame structure comprising a plurality of radio subframescomprising radio resource blocks arranged in time and frequency, andwherein the indication of radio resources for receiving user-plane dataon the first carrier corresponds with a first radio resource blockarrangement within a subframe of the first carrier and the indication ofradio resources for receiving user-plane data on the second carriercorresponds with a second radio resource block arrangement within asubframe of the second carrier.

Paragraph 23. The method of paragraph 22, wherein the first radioresource block arrangement is the same as the second radio resourceblock arrangement.

Paragraph 24. The method of paragraph 22, wherein the first radioresource block arrangement is not the same as the second radio resourceblock arrangement.

Paragraph 25. The method of paragraph 24, further comprising derivingone of the first and second radio resource block arrangements from theother of the first and second radio resource block arrangements based ona predefined relationship between them.

Paragraph 26. The method of any of paragraphs 18 to 25, wherein theuser-plane data received by the second terminal device on the secondcarrier is the same as the user-plane data received by the secondterminal device on the first carrier.

Paragraph 27. The method of any of paragraphs 18 to 26, wherein theuser-plane data received by the second terminal device on the secondcarrier is not the same as the user-plane data received by the secondterminal device on the first carrier.

Paragraph 28. The method of any of paragraphs 18 to 27, wherein thecontrol signalling further comprises an indication of whether or not theuser-plane data received by the second terminal device on the secondcarrier is the same as the user-plane data received by the secondterminal device on the first carrier.

Paragraph 29. The method of any of paragraphs 18 to 28, wherein theradio resources on the second carrier indicated by the controlsignalling are for times which are different from the times of the radioresources on the first carrier indicated by the control signalling.

Paragraph 30. The method of any of paragraphs 17 to 29, furthercomprising receiving on the second carrier control signalling comprisingan indication of the radio resources on the second carrier to be used byth second terminal device for receiving user-plane data from the firstterminal device.

Paragraph 31. A second terminal device for receiving data from a firstterminal device in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band, wherein the second terminal devicecomprises a controller unit and a transceiver unit configured to operatetogether to:

receive on the first carrier control signalling comprising an indicationof radio resources on the second carrier to be used by the firstterminal device for transmitting user-plane data to the second terminaldevice; and

receive user-plane data from the first terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

Paragraph 32. Circuitry for a second terminal device for receiving datafrom a first terminal device in a device-to-device communication mode ina wireless telecommunications system supporting communications on afirst carrier operating over a first frequency band and a second carrieroperating over a second frequency band, wherein the circuitry comprisesa controller element and a transceiver element configured to operatetogether to cause the second terminal device to:

receive on the first carrier control signalling comprising an indicationof radio resources on the second carrier to be used by the firstterminal device for transmitting user-plane data to the second terminaldevice; and

receive user-plane data from the first terminal device on the secondcarrier using the radio resources on the second carrier indicated by thecontrol signalling.

Second Group of Numbered Paragraphs

Paragraph 1. A method of operating a first terminal device fortransmitting data to a second terminal device in a device-to-devicecommunication mode in a wireless telecommunications system supportingcommunications on a first carrier operating over a first frequency bandand a second carrier operating over a second frequency band; the methodcomprising:

transmitting on the first carrier control signalling comprising anindication that the first terminal device intends to transmit data tothe second terminal device using the device-to-device communication modeon the second carrier after a carrier switch-over time; and

after the carrier switch-over time, transmitting data to the secondterminal device on the second carrier using the device-to-devicecommunication mode.

Paragraph 2. The method of paragraph 1, wherein the control signallingconveys an indication of the carrier switch-over time.

Paragraph 3. The method of paragraph 2, wherein the carrier switch-overtime is determined from a time associated with when the controlsignalling is transmitted.

Paragraph 4. The method of paragraph 3, wherein the carrier switch-overtime corresponds with the time at which the control signalling istransmitted.

Paragraph 5. The method of paragraph 3, wherein the carrier switch-overtime corresponds with the time at which the control signalling istransmitted plus a switch-over delay period.

Paragraph 6. The method paragraph 5, wherein the control signalling istransmitted by the first terminal device in one of a plurality ofcontrol signalling time windows defined in accordance with a controlsignalling schedule for the first terminal device, and wherein thecarrier switch-over time is based on the time of a control signallingtime window that follows the control signalling time window in which thecontrol signalling is transmitted.

Paragraph 7. The method of any of paragraphs 2 to 6, wherein the controlsignalling comprises an explicit indication of the carrier switch-overtime.

Paragraph 8. The method paragraph 7, wherein the control signalling istransmitted by the first terminal device in one of a plurality ofcontrol signalling time windows defined in accordance with a controlsignalling schedule for the first terminal device, and wherein theexplicit indication of the carrier switch-over time comprises anindication of a control signalling time window that follows the controlsignalling time window in which the control signalling is transmitted,wherein the carrier switch-over time is based on the time of theindicated control signalling time window.

Paragraph 9. The method of any of paragraphs 1 to 8, further comprisingafter transmitting data to the second terminal device on the secondcarrier using the device-to-device communication mode, reverting totransmitting data to the second terminal device on the first carrierusing the device-to-device communication mode after a carrierswitch-back time.

Paragraph 10. The method of paragraph 9, wherein the control signallingconveys an indication of the carrier switch-back time.

Paragraph 11. The method of paragraph 10, wherein the carrierswitch-back time is determined from a time associated with when thecontrol signalling is transmitted.

Paragraph 12. The method of paragraph 11, wherein the carrierswitch-back time corresponds with the time at which the controlsignalling is transmitted plus a switch-back delay period.

Paragraph 13. The method paragraph 12, wherein the control signalling istransmitted by the first terminal device in one of a plurality ofcontrol signalling time windows defined in accordance with a controlsignalling schedule for the first terminal device, and wherein thecarrier switch-back time is based on the time of a control signallingtime window that follows the control signalling time window in which thecontrol signalling is transmitted.

Paragraph 14. The method of any of paragraphs 9 to 13, wherein thecontrol signalling comprises an explicit indication of the carrierswitch-back time.

Paragraph 15. The method paragraph 14, wherein the control signalling istransmitted by the first terminal device in one of a plurality ofcontrol signalling time windows defined in accordance with a controlsignalling schedule for the first terminal device, and wherein theexplicit indication of the carrier switch-back time comprises anindication of a control signalling time window that follows the controlsignalling time window in which the control signalling is transmitted,wherein the carrier switch-back time is based on the time of theindicated control signalling time window.

Paragraph 16. The method of any of paragraphs 1 to 15, wherein thecontrol signalling further comprises an indication of radio resources onthe first carrier to be used for transmitting user-plane data from thefirst terminal device to the second terminal device before the carrierswitch-over time.

Paragraph 17. The method of any of paragraphs 1 to 16, wherein thecontrol signalling further comprises an indication of radio resources onthe second carrier to be used for transmitting user-plane data from thefirst terminal device to the second terminal device after the carrierswitch-over time.

Paragraph 18. A first terminal device for transmitting data to a secondterminal device in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band, wherein the first terminal devicecomprises a controller unit and a transceiver unit configured to operatetogether to:

transmit on the first carrier control signalling comprising anindication that the first terminal device intends to transmit data tothe second terminal device using the device-to-device communication modeon the second carrier after a carrier switch-over time; and

after the carrier switch-over time, transmit data to the second terminaldevice on the second carrier using the device-to-device communicationmode.

Paragraph 19. Circuitry for a first terminal device for transmittingdata to a second terminal device in a device-to-device communicationmode in a wireless telecommunications system supporting communicationson a first carrier operating over a first frequency band and a secondcarrier operating over a second frequency band, wherein the circuitrycomprises a controller element and a transceiver element configured tooperate together to cause the first terminal device to:

transmit on the first carrier control signalling comprising anindication that the first terminal device intends to transmit data tothe second terminal device using the device-to-device communication modeon the second carrier after a carrier switch-over time; and

after the carrier switch-over time, transmit data to the second terminaldevice on the second carrier using the device-to-device communicationmode.

Paragraph 20. A method of operating a second terminal device forreceiving data from a first terminal device in a device-to-devicecommunication mode in a wireless telecommunications system supportingcommunications on a first carrier operating over a first frequency bandand a second carrier operating over a second frequency band; the methodcomprising:

receiving on the first carrier control signalling comprising anindication that the first terminal device intends to transmit data tothe second terminal device using the device-to-device communication modeon the second carrier after a carrier switch-over time; and

after the carrier switch-over time, receiving data from the terminaldevice on the second carrier using the device-to-device communicationmode.

Paragraph 21. The method of paragraph 20, wherein the control signallingconveys an indication of the carrier switch-over time.

Paragraph 22. The method of paragraph 21, wherein the carrierswitch-over time is determined from a time associated with when thecontrol signalling is received.

Paragraph 23. The method of paragraph 22, wherein the carrierswitch-over time corresponds with the time at which the controlsignalling is received.

Paragraph 24. The method of paragraph 22, wherein the carrierswitch-over time corresponds with the time at which the controlsignalling is received plus a switch-over delay period.

25. The method paragraph 24, wherein the control signalling is receivedby the second Paragraph terminal device in one of a plurality of controlsignalling time windows defined in accordance with a control signallingschedule for the first terminal device, and wherein the carrierswitch-over time is based on the time of a control signalling timewindow that follows the control signalling time window in which thecontrol signalling is received.

Paragraph 26. The method of any of paragraphs 21 to 25, wherein thecontrol signalling comprises an explicit indication of the carrierswitch-over time.

Paragraph 27. The method paragraph 26, wherein the control signalling isreceived by the second terminal device in one of a plurality of controlsignalling time windows defined in accordance with a control signallingschedule for the first terminal device, and wherein the explicitindication of the carrier switch-over time comprises an indication of acontrol signalling time window that follows the control signalling timewindow in which the control signalling is received, wherein the carrierswitch-over time is based on the time of the indicated controlsignalling time window.

Paragraph 28. The method of any of paragraphs 20 to 27, furthercomprising after receiving data from the first terminal device on thesecond carrier using the device-to-device communication mode, revertingto receiving data from the first terminal device on the first carrierusing the device-to-device communication mode after a carrierswitch-back time.

Paragraph 29. The method of paragraph 28, wherein the control signallingconveys an indication of the carrier switch-back time.

Paragraph 30. The method of paragraph 29, wherein the carrierswitch-back time is determined from a time associated with when thecontrol signalling is received.

Paragraph 31. The method of paragraph 30, wherein the carrierswitch-back time corresponds with the time at which the controlsignalling is received plus a switch-back delay period.

Paragraph 32. The method paragraph 31, wherein the control signalling isreceived by the second terminal device in one of a plurality of controlsignalling time windows defined in accordance with a control signallingschedule for the first terminal device, and wherein the carrierswitch-back time is based on the time of a control signalling timewindow that follows the control signalling time window in which thecontrol signalling is received.

Paragraph 33. The method of any of paragraphs 28 to 32, wherein thecontrol signalling comprises an explicit indication of the carrierswitch-back time.

Paragraph 34. The method paragraph 33, wherein the control signalling isreceived by the second terminal device in one of a plurality of controlsignalling time windows defined in accordance with a control signallingschedule for the first terminal device, and wherein the explicitindication of the carrier switch-back time comprises an indication of acontrol signalling time window that follows the control signalling timewindow in which the control signalling is received, wherein the carrierswitch-back time is based on the time of the indicated controlsignalling time window.

Paragraph 35. The method of any of paragraphs 20 to 34, wherein thecontrol signalling further comprises an indication of radio resources onthe first carrier to be used by the second terminal device for receivinguser-plane data from the first terminal device before the carrierswitch-over time.

Paragraph 36. The method of any of paragraphs 20 to 35, wherein thecontrol signalling further comprises an indication of radio resources onthe second carrier to be used by the second terminal device forreceiving user-plane data from the first terminal device before thecarrier switch-over time.

Paragraph 37. A second terminal device for receiving data from a firstterminal device in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band; wherein the second terminal devicecomprises a controller unit and a transceiver unit configured to operatetogether to receive on the first carrier control signalling comprisingan indication that the first terminal device intends to transmit data tothe second terminal device using the device-to-device communication modeon the second carrier after a carrier switch-over time; and after thecarrier switch-over time, receive data from the terminal device on thesecond carrier using the device-to-device communication mode.

Paragraph 38. Circuitry for a second terminal device for receiving datafrom a first terminal device in a device-to-device communication mode ina wireless telecommunications system supporting communications on afirst carrier operating over a first frequency band and a second carrieroperating over a second frequency band, wherein the circuitry comprisesa controller element and a transceiver element configured to operatetogether to cause the second terminal device to:

receive on the first carrier control signalling comprising an indicationthat the first terminal device intends to transmit data to the secondterminal device using the device-to-device communication mode on thesecond carrier after a carrier switch-over time; and

after the carrier switch-over time, receive data from the terminaldevice on the second carrier using the device-to-device communicationmode.

REFERENCES

-   [1] LTE for UMTS: OFDMA and SC-FDMA Based Radio Access, Harris Holma    and Antti Toskala, Wiley 2009, ISBN 978-0-470-99401-6.-   [2] R2-133840, “CSMA/CA based resource selection,” Samsung,    published at 3GPP TSG-RAN WG2 #84, San Francisco, USA, 11-15 Nov.    2013.-   [3] R2-133990, “Network control for Public Safety D2D    Communications”, Orange, Huawei, HiSilicon, Telecom Italia,    published at 3GPP TSG-RAN WG2 #84, San Francisco, USA, 11-15 Nov.    2013.-   [4] R2-134246, “The Synchronizing Central Node for Out of Coverage    D2D Communication”, General Dynamics Broadband UK, published at 3GPP    TSG-RAN WG2 #84, San Francisco, USA, 11-15 Nov. 2013.-   [5] R2-134426, “Medium Access for D2D communication”, LG Electronics    Inc, published at 3GPP TSG-RAN WG2 #84, San Francisco, USA, 11-15    Nov. 2013.-   [6] R2-134238, “D2D Scheduling Procedure”, Ericsson, published at    3GPP TSG-RAN WG2 #84, San Francisco, USA, 11-15 Nov. 2013.-   [7] R2-134248, “Possible mechanisms for resource selection in    connectionless D2D voice communication”, General Dynamics Broadband    UK, published at 3GPP TSG-RAN WG2 #84, San Francisco, USA, 11-15    Nov. 2013.-   [8] R2-134431, “Simulation results for D2D voice services using    connectionless approach”, General Dynamics Broadband UK, published    at 3GPP TSG-RAN WG2 #84, San Francisco, USA, 11-15 Nov. 2013.-   [9] “D2D Resource Allocation under the Control of BS”, Xiaogang R.    et al, University of Electronic Science and Technology of China,    https    //mentor.ieee.org/802.16/dcn/13/16-13-0123-02-000n-d2d-resource-allocation-under-the-control-of-bs.docx-   [10] US 2013/0170387-   [11] US 2012/0300662

1. A method of operating a first terminal device for transmitting datato a second terminal device in a device-to-device communication mode ina wireless telecommunications system supporting communications on afirst carrier operating over a first frequency band and a second carrieroperating over a second frequency band; the method comprising:transmitting on the first carrier control signalling comprising anindication of radio resources on the second carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device; and transmitting user-plane data to the secondterminal device on the second carrier using the radio resources on thesecond carrier indicated by the control signalling.
 2. The method ofclaim
 1. wherein the control signalling further comprises an indicationof radio resources on the first carrier to be used for transmittinguser-plane data from the first terminal device to the second terminaldevice, and wherein the method further comprises transmitting user-planedata to the second terminal device on the first carrier using the radioresources on the first carrier indicated by the control signalling. 3.The method of claim 2, wherein the indication of radio resources on thesecond carrier and the indication of radio resources on the firstcarrier are provided by a common indication that is applicable to bothcarriers.
 4. The method of claim 2, wherein the each of the first andsecond carriers operate over a radio interface having a radio framestructure comprising a plurality of radio subframes, and wherein controlsignalling in each radio subframe of the first carrier comprises anindication of whether the control signalling is providing: (i) anindication of radio resources on the first carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device; or (ii) an indication of radio resources on thesecond carrier to be used for transmitting user-plane data from thefirst terminal device to the second terminal device; or (iii) anindication of radio resources on both the first and second carriers tobe used for transmitting user-plane data from the first terminal deviceto the second terminal device.
 5. The method of claim 2, wherein theindication of radio resources on the second carrier and the indicationof radio resources on the first carrier are provided as separateindications.
 6. The method of claim 2, wherein each of the first andsecond carriers operate over a radio interface having a radio framestructure comprising a plurality of radio subframes comprising radioresource blocks arranged in time and frequency, and wherein theindication of radio resources for transmitting user-plane data on thefirst carrier corresponds with a first radio resource block arrangementwithin a subframe of the first carrier and the indication of radioresources for transmitting user-plane data on the second carriercorresponds with a second radio resource block arrangement within asubframe of the second carrier.
 7. The method of claim 6, wherein thefirst radio resource block arrangement is the same as the second radioresource block arrangement.
 8. The method of claim 6, wherein the firstradio resource block arrangement is not the same as the second radioresource block arrangement.
 9. The method of claim 8, further comprisingderiving one of the first and second radio resource block arrangementsfrom the other of the first and second radio resource block arrangementsbased on a predefined relationship between them.
 10. The method of claim2, wherein the user-plane data transmitted to the second terminal deviceon the second carrier is the same as the user-plane data transmitted tothe second terminal device on the first carrier.
 11. The method of claim2, wherein the user-plane data transmitted to the second terminal deviceon the second carrier is not the same as the user-plane data transmittedto the second terminal device on the first carrier.
 12. The method ofclaim 2, wherein the control signalling further comprises an indicationof whether or not the user-plane data transmitted to the second terminaldevice on the second carrier is the same as the user-plane datatransmitted to the second terminal device on the first carrier.
 13. Themethod of claim 2, wherein the radio resources on the second carrierindicated by the control signalling are for times which are differentfrom the times of the radio resources on the first carrier indicated bythe control signalling.
 14. The method of claim 1, further comprisingtransmitting on the second carrier control signalling comprising anindication of the radio resources on the second carrier to be used fortransmitting user-plane data from the first terminal device to thesecond terminal device.
 15. A first terminal device for transmittingdata to a second terminal device in a device-to-device communicationmode in a wireless telecommunications system supporting communicationson a first carrier operating over a first frequency band and a secondcarrier operating over a second frequency band, wherein the firstterminal device comprises a controller unit and a transceiver unitconfigured to operate together to transmit on the first carrier controlsignalling comprising an indication of radio resources on the secondcarrier to be used for transmitting user-plane data from the firstterminal device to the second terminal device; and transmit user-planedata to the second terminal device on the second carrier using the radioresources on the second carrier indicated by the control signalling. 16.Circuitry for a first terminal device for transmitting data to a secondterminal device in a device-to-device communication mode in a wirelesstelecommunications system supporting communications on a first carrieroperating over a first frequency band and a second carrier operatingover a second frequency band, wherein the circuitry comprises acontroller element and a transceiver element configured to operatetogether to cause the first terminal device to: transmit on the firstcarrier control signalling comprising an indication of radio resourceson the second carrier to be used for transmitting user-plane data fromthe first terminal device to the second terminal device; and transmituser-plane data to the second terminal device on the second carrierusing the radio resources on the second carrier indicated by the controlsignalling.
 17. A method of operating a second terminal device forreceiving data from a first terminal device in a device-to-devicecommunication mode in a wireless telecommunications system supportingcommunications on a first carrier operating over a first frequency bandand a second carrier operating over a second frequency band: the methodcomprising: receiving on the first carrier control signalling comprisingan indication of radio resources on the second carrier to be used by thefirst terminal device for transmitting user-plane data to the secondterminal device: and receiving user-plane data from the first terminaldevice on the second carrier using the radio resources on the secondcarrier indicated by the control signalling. 18-32. (canceled)